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).     

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.     

[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.     

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.     

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.     

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.     

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.     

Studies on the mechanism of thyrotropin releasing hormone induced inhibition of gastrointestinal transit

Intracerebral administration of thyrotropin releasing hormone (TRH) inhibited gastrointestinal transit in the mouse as determined by the charcoal meal test. A similar inhibitory effect was produced by morphine administered subcutaneously. TRH enhanced morphine-induced inhibition of gastrointestinal transit. Intracerebral injections of cyclo (His-Pro), a postulated metabolite, did not affect gastrointestinal transit either by itself or that produced by morphine. It is suggested that gastrointestinal transit effects of TRH are not mediated via its conversion to cyclo (His-Pro).     

Analog specificity of the thyrotropin-releasing hormone receptor in the central nervous system: possible clinical implications

TRH has rapid-onset (30 sec), slow-offset (1-12 days) clinical benefit in patients with amyotrophic lateral sclerosis and other motor neuron disorders. This benefit is probably receptor-mediated and may have at least 2 components. To obtain a better understanding of the various responses to TRH of the spinal lower motor neurons (LMNs) in patients, and possibly to help guide selection of additional therapeutic agents, we utilized rat CNS (spinal-cord and brain membranes) to analyze the ability of certain molecules to inhibit specific binding of [3H]methyl TRH [( 3H]MeTRH) to the TRH receptor. We found: a) lack of high-affinity binding of the TRH-analog DN-1417 by spinal-cord and brain TRH receptor, despite its known strong TRH-like action physiologically on LMNs; b) lack of high-affinity binding of the TRH-product cyclo(His-Pro) by spinal-cord and brain TRH receptor despite its having some strong TRH-like physiologic actions on the CNS; and c) lack of any identifiable high-affinity receptor for cyclo(His-Pro) in spinal cord and brain. From these data we hypothesize that the acute transmitter-like action of DN-1417, TRH, and possibly other TRH-analogs and products on LMNs is via a non-TRH receptor, such as an amine or amino acid neurotransmitter receptor, e.g. a 5-hydroxytryptamine receptor. We further postulate that the CNS TRH-receptor may modulate a trophic-like influence of TRH on LMNs.     

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.     

Specific binding to adrenal particulate fraction of cyclo(histidyl-proline), a TRH metabolite

Histidyl-proline diketopiperazine (cyclo(His-Pro), a metabolite of the neuropeptide thyrotropin releasing hormone, has been shown to possess intrinsic biological activities. The binding of this peptide to various tissue particulate preparations was investigated. While the peptide showed no apparent binding to particulate fractions derived from brain, pituitary, and some other tissues, binding to adrenal and liver was demonstrated. The binding of cyclo(His-Pro) to bovine adrenal cortical particles was further characterized. Binding at equilibrium was greater at 4 degrees C than at 37 degrees C. The binding was dependent on tissue concentration, showed a pH optimum between 7 and 8, and was inactivated by treatment of the particulate fraction with trypsin or by boiling. The interaction of cyclo(His-Pro) with the tissue was not associated with any metabolism of the peptide. Kinetic studies of association of cyclo(His-Pro) with adrenal cortical particles indicated a single class of binding sites with a KD of approximately 900 nM and a maximum number of sites of 92 pmoles/mg protein. The binding was stereospecific and the histidine moiety of the peptide was the major determinant of the binding. A variety of catechols, serotonin and histamine competed with cyclo(His-Pro) for binding with IC50's ranging from 17-450 muM. Cyclo(His-Pro) did not affect monoamine oxidase or adenylate cyclase activity in adrenal cortical particulate preparations.     

Thyrotrophin-releasing hormone inactivation by human postmortem brain

The mechanisms of inactivation of thyrotrophin-releasing hormone (TRH) by peptidases in several areas of normal human postmortem brain have been investigated by radioimmunoassay and high-performance liquid chromatography. Of the several brain regions studied, the cerebral cortex (Brodman's area, BA10) had the highest TRH-degrading activity in both subcellular fractions. Deamidated-TRH (TRH-OH) was the only product formed by the soluble fraction whereas the histidyl-proline diketopiperazine, cyclo(His-Pro), and a small amount of TRH-OH were formed by the particulate fraction. Several centrally acting TRH analogues showed varying degrees of resistance to degradation by the peptidases in the two fractions, the most stable analogue being RX77368 (pGlu-His-3,3'-dimethyl(ProNH2]. Areas of human postmortem brain appear to contain two of the enzymes capable of degrading TRH, a proline endopeptidase forming TRH-OH and a pyroglutamyl aminopeptidase forming cyclo(His-Pro). The use of the assay procedures in further studies on the inactivation of TRH by peptidases from brain areas of patients with neurological disorders may provide complementary information on the dynamics of TRH in these disorders. The stability of the centrally acting TRH analogues may prove useful in examining their therapeutic potential.     

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.     

Evidence for the presence of immunoreactive histidyl-proline diketopiperazine [Cyclo (His-Pro)] in the adult human brain

The current study was undertaken to evaluate the presence of cyclo (His-Pro) in adult human brain tissues obtained at autopsy. We found evidence for immunoreactive cyclo (His-Pro), which diluted in parallel to the radioimmunoassay standard curve and which had mobility on HPLC that was similar to synthetic cyclo (His-Pro), in several regions of the adult human brain. Whereas the levels of cyclo (His-Pro) in the pituitary stalk-median eminence were high (2.2 ng/mg protein), the concentrations in the whole hypothalamus were much lower (0.105 ng/mg protein). Among the extrahypothalamic brain regions examined, the levels of cyclo (His-Pro) were highest in the cerebellar hemisphere (0.168 ng/mg protein) and olfactory bulbs (0.180 ng/mg protein) and were lowest in the hippocampus (0.080 ng/mg protein) and occipital cortex (0.079 ng/mg protein). Thus, immunoreactive cyclo (His-Pro) has widespread distribution in the adult human brain and the potential exists for this cyclic diepeptide to play a role in human brain function.     

Inhibition of abstinence syndrome in opiate defendent mice by cyclo (His-Pro)

Intracerebral administration of cyclo (His-Pro), the postulated metabolite of thyroliberin (TRH, pGlu-His-Pro-NH₂) inhibited the naloxone induced withdrawal responses in morphine dependent mice. Mice were rendered dependent on morphine by the subcutaneous implantation of a pellet (containing 75 mg of morphine free base) for three days. Six hours after pellet removal, the naloxone ED₅₀ for the jumping response was found to be higher in mice injected with cyclo (His-Pro) compared with that of vehicle controls. Similarly, the hypothermic response observed following 50 μg/kg of naloxone given given 6 h after pellet removal or that seen with 100 μg/kg of naloxone given 24 h after pellet removal from morphine-dependent mice was inhibited by cyclo (His-Pro). Previously, we have shown similar results with TRH on the morphine abstinence syndrome. It appears, therefore, that cyclo (His-Pro) may be the active metabolite of TRH and analogs of cyclo (His-Pro) may be useful in blocking the symptoms of the opiate abstinence syndrome.     

Lack of effect of histidyl-proline diketopiperazine on basal level and TRH-induced response of cytosolic calcium concentration in rat lactotrophs.

Histidyl-proline diketopiperazine [cyclo(His-Pro)] has recently been shown to inhibit prolactin (PRL) secretion in vitro and in vivo. This peptide is well known as a metabolite of thyrotropin-releasing hormone (TRH), which is one of the endogenous secretagogues of PRL. In this study, we investigated the effect of cyclo (His-Pro) on the cytosolic Ca2+ concentration [[Ca2+]i) in cultured lactotrophs by using a lactotroph-enriched fraction separated from female rat pituicytes by centrifugal elutriation. TRH (10 nM) induced a rapid rise in [Ca2+]i in the lactotrophs, followed by a plateau phase of prolonged increase in [Ca2+]i. In contrast, the addition of 100 microM of cyclo (His-Pro) caused no changes in the basal level or the TRH-induced plateau response of [Ca2+]i. Although pretreatment with cyclo (His-Pro) tended to decrease the biphasic increase in [Ca2+]i induced by TRH, the inhibitory effect was not statistically significant. These results demonstrated that cyclo (His-Pro) has no effect on [Ca2+]i in lactotrophs, and does not affect the TRH-induced increase in [Ca2+]i, indicating that the inhibition of PRL secretion by cyclo (His-Pro) may be primarily mediated by other intracellular messengers such as cyclic nucleotides and secondarily involved in other inhibitory systems including that of dopamine.     

Pyroglutamate aminopeptidase in rat submaxillary gland.

A significant amount of pyroglutamate aminopeptidase (PGAP) activity was found to be present in 27,000 x g supernatant of rat submaxillary gland, maximum activity being at pH 6.5. EDTA stimulated the enzyme activity by 95% at pH 8.0 while at pH 6.5 it did not have any significant effect. On comparison of its properties submaxillary PGAP appears to be different from brain, pituitary and other reported PGAPs. Submaxillary PGAP could also catalyze efficiently the formation of cyclo (His-Pro) from TRH. Cyclo (His-Pro) formation by submaxillary enzyme was more pronounced than that by liver PGAP.     

Distribution and characterization of cyclo(His-Pro)-like immunoreactivity in human cerebrospinal fluid

The distribution of cyclo(His-Pro), thyrotropin-releasing hormone and pyroglutamate aminopeptidase activity was examined in the CSF of human and a number of other mammalian species. Cyclo(His-Pro)-like immunoreactivity was present in the CSF of all species examined, and was immunologically and chromatographically identical with the authentic cyclo(His-Pro). Cyclo(His-Pro) concentration in CSF had no significant correlation with CSF TRH or pyroglutamate aminopeptidase.     

Structure activity relationship studies with hypothalamic peptide hormones. II. Effects of thyrotropin releasing hormone analogs on morphine-induced responses in mice

The effects of several analogs of thyroliberin (TRH), that have a chloro-acetyl substituent at the amino terminus, on locomotor depressant, locomotor stimulant, hyperthermic and hypothermic response to morphine were determined in the mouse. These compounds included N-(chloroacetyl)-L-phenylalanylpyrrolidine (ClAc-Phe-Pyrr), N-[m-(chloroacetyl)benzoyl]-L-phenylalanylpyrrolidine] (mClAcBz-Phe-Pyrr), N-[m-(chloroacetyl)benzoyl]-L-alanyl-L-phenylalanylpyrrolidine (mClAcBz-Ala-Phe-Pyrr), N-[p-(chloroacetyl)benzoyl]-L-alanyl-L-phenylalanyl-pyrrolidine (pClAcBz-Ala-Phe-Pyrr), N-(chloroacytyl)-L-alanyl-L-phenylalanyl-L-prolineamide(ClAc-Ala-Phe-Pro-NH₂), N-[m-(chloroacetyl)-benzoyl]-L-phenylalanyl-L-prolineamide (mClAcBz-Phe-Pro-NH₂), N-[p-(chloroacetyl)benzoyl]-L-phenylalanyl-L-prolineamide (pClAcBz-Phe-Pro-NH₂). Since TRH is metabolized to cyclo (His-Pro) and the latter is shown to possess TRH like activity, an analog cyclo (Phe-Pro) was also used. Administration of morphine to mice at 10 mg/kg ip produced hyperthermia and depression in locomotor activity, while at 80 mg/kg ip, hypothermia and stimulation in locomotor activity were observed. Intracerebral injection of the following peptides (10 μg each per mouse) administered 10 min prior to morphine injection antagonized locomotor depression, hyperthermia, locomotor stimulation and hypothermia induced by an appropriate dose of morphine: mClAcBz-Phe-Pyrr, pClAcBz-Ala-Phe-Pyrr, ClAcAla-Phe-Pro-NH₂, pClAcBz-Phe-Pro-NH₂, cyclo (Phe-Pro) and TRH. The compounds which had no effect on low dose or high dose morphine induced responses included pGlu-Phe-Pyrr, mClAcBz-Ala-Phe-Pyrr, and mClAcBz-Phe-Pro-NH₂. One compound, namely ClAc-Phe-Pyrr, antagonized morphine-induced locomotor stimulation and hypothermia but did not affect locomotor depression and hyperthermia produced by morphine. None of these peptides had any effect on the body temperature or the locomotor activity of normal mice. Many of the active compounds were previously shown to possess extremely weak or no activity in releasing thyrotropin from the pituitary. It is concluded that several of these analogs of TRH possess CNS activity in antagonizing morphine effects, and that a lack of relationship exists between the CNS and endocrine activity of these peptides.