Imidazole-substituted analogues of TRH limit behavioral deficits after experimental brain trauma.

Treatment with thyrotropin releasing hormone (TRH) or TRH analogues improves outcome after experimental brain or spinal cord trauma. TRH analogues with modifications at the N-terminal position of the tripeptide are effective, whereas analogues with modifications of the C-terminal residue are not. Imidazole-substituted TRH analogues, which modify the middle amino acid (histidine) of the tripeptide, have more recently been developed but have not been evaluated in models of central nervous system (CNS) trauma. In the present studies two imidazole-substituted analogues--4(5)-NO2(Im)TRH and 2,4 diiodo(Im)TRH--are shown to improve behavioral recovery following fluid percussion-induced traumatic brain injury (TBI) in rats. Because 4(5)-NO2(Im)TRH has little endocrine activity and 2,4 diiodo(Im)TRH has minimal cardiovascular effects, these experiments support the hypothesis that the neuroprotective actions of TRH analogues are independent of their endocrine or autonomic actions.

Biological activities of thionated thyrotropin-releasing hormone analogs.

Analogs of thyrotropin-releasing hormone (Glp-His-Pro-NH2, TRH) have been prepared which contain thioamide moieties in the pyroglutamic acid ring, the carboxyamide proline terminus, and in both positions (dithio). These compounds have been tested for TSH-releasing activities (in vitro and in vivo), and for binding to TRH receptors in rat pituitary and cortex. The monothionated analogs showed no significant differences in TSH-releasing potency from TRH either in vitro or in vivo. However, with two thioamide replacements the potency decreases about 50%. Significantly, in terms of receptor selectivity, thionation has resulted in differentiation between brain receptors (pituitary and cortex). The Pro psi[CSNH2] and dithio analogs were more selective (higher affinity to pituitary receptors) than the parent hormone, while the analog containing a thioamide replacement in the pyroglutamyl ring had lower affinity and was not selective. These results suggest that the subtle exchange of sulphur for oxygen can have an important impact on both receptor selectivity and affinity within a biologically active peptide.

Direct electrophilic fluorination of tyrosine in dermorphin analogues and its effect on biological activity, receptor affinity and selectivity.

In a preliminary communication we reported [(Tetrahedron Lett. 31, 619 (1990)] that acetyl hypofluorite can be used efficiently to introduce fluorine regiospecifically (ortho to OH) into the phenolic ring of tyrosine-containing peptides. This procedure has been applied to the fluorination of a number of mu-selective opioid peptides derived from dermorphin. While the procedure can be used even when the side chains of Arg, Lys, and Tyr are left unprotected, the sulfoxide of a Met(O)-containing analogue was oxidized to sulfone faster than fluorination of the phenolic ring. This method can also be used when the peptide is attached to Merrifield resin. Thus, Tyr(3-F)-D-Ala-Phe-Gly-NH2 and Tyr(3-F)-D-Arg-Phe-Lys-NH2 (F-DALDA) have been prepared, purified, and characterized. Affinities of these fluorinated peptides for both mu- and delta- opioid receptors are reduced (two- to nine-fold) relative to their nonfluorinated analogues, but their selectivity for mu-opioid receptors is not significantly altered. Similarly, the in vitro biological potencies (GPI and MVD assays) of the fluorinated analogues are reduced (two- to seven-fold) relative to their nonfluorinated parent peptides. Thus, F-DALDA, which has high affinity (Ki mu = 15.2 nM) and selectivity (Ki delta/Ki mu = 5390) for mu-opioid receptors, has potential use in biochemical studies which utilize 19F or 18F- labeled compounds.

Selective cardiorespiratory activity of an iodinated analog of thyrotropin-releasing hormone (TRH).

The biological activity of thyrotropin-releasing hormone (TRH) and its analogs 4(5)-I-Im-TRH and 2,4(5)-I2-Im-TRH was assessed by means of their effects on: 1) the mean arterial pressure (MAP), 2) heart rate (HR), 3) ventilation minute volume (MV), 4) contractility of the rat duodenum, and 5) concentrations of thyrotropin (TSH) or prolactin (PRL) in serum. Also their binding to TRH-receptors in brain homogenates was studied. In urethane-anesthetized rats TRH ICV increased MAP, HR and MV. 4(5)-I-Im-TRH was equally as active as TRH on HR and MV but a significant elevation in MAP was observed only at a dose 100-fold to that of TRH. However, the maximal responses of 4(5)-I-Im-TRH and TRH did not differ. In conscious rats, TRH 1A elevated MAP and HR but 4(5)-I-Im-TRH was active on MAP only. 2,4(5)-I2-Im-TRH was devoid of cardiorespiratory activity. TRH dose-dependently inhibited the contractions of the rat duodenum while the iodinated analogs lacked such an activity. To induce a significant release of TSH several hundred times more of 4(5)-I-Im-TRH and over 1000 times more of 2,4(5)-I2-Im-TRH were needed as compared to TRH. The iodoanalogs elevated PRL levels only at doses 2000-fold higher than those of TRH. The iodoanalogs displaced [3H][3-Me-His2]TRH [( 3H]MeTRH) from its binding sites at concentrations about 1000 times higher than those of TRH. Substitutions of the histidyl moiety of TRH in 4(5)-I-Im-TRH and 2,4(5)-I2-Im-TRH resulted in substantial loss of the endocrine activity. While the di-iodinated analog was practically devoid of any biological activity the monoiodinated analog exerted similar cardiorespiratory activity to that of TRH.

Norvaline2-TRH: binding to TRH receptors in rat brain homogenates.

Norvaline2-thyrotropin-releasing hormone ([Nva2]TRH) has been described as a thyrotropin-releasing hormone (TRH) analog with no thyrotropin (TSH)-releasing capacity but enhanced analeptic activity compared with TRH, as shown by the reversal of haloperidol-induced catalepsy. We have evaluated the receptor-binding properties of [Nva2]TRH in homogenates of rat anterior pituitary, hypothalamus, brainstem and cortex tissue, using [3H]TRH and [3H][3-Me-His2]TRH as radioligands. Apparent Ki values at high affinity TRH-binding sites, labelled predominantly by [3H][3-Me-His2]TRH, ranged from 17.0 to 36.9 microM in all tested regions. Additionally, [Nva2]TRH was shown to compete with [3H]TRH at low affinity TRH-binding sites with similar affinities. It is concluded that the loss of TSH-releasing activity of [Nva2]TRH appears to be due to a drastic reduction in binding affinity to the high affinity TRH receptor subtype. Its analeptic activity, however, may be mediated by low affinity TRH binding sites which are predominantly labelled by [3H]TRH or by yet unidentified mechanisms.

Receptor binding of fluorinated histidine analogs of thyrotropin-releasing hormone in various regions of the rat brain.

Binding properties of [4(5)-fluoro-imidazole-His2]-TRH (4(5)-F-TRH), [2-trifluoromethyl-imidazole-His2]-TRH (2-CF3-TRH) and [4(5)-trifluoromethyl-imidazole-His2]-TRH (4(5)-CF3-TRH), three novel TRH analogs, have been evaluated in rat pituitary, hypothalamus, brainstem and cortex tissue. 4(5)-F-TRH, previously shown to elicit arterial pressor responses and prolactin release similar to those of TRH, binds to TRH receptors with low, micromolar affinity (Ki = 7.5-13.5 microM). 2-CF3-TRH, an analog of less cardiovascular but increased prolactin-releasing activity, shows Ki values of 3.3-4.9 microM. 4(5)-CF3-TRH, which shows comparable biological activity to 2-CF3-TRH, demonstrates a binding affinity which is virtually nonspecific (Ki = 0.39-1.01 mM). It is therefore concluded that the biological effects of these analogs are mediated either through low affinity TRH binding sites not recognized by [3H][3Me-His2]-TRH or through mechanisms not involving TRH receptors as such.

In vitro and in vivo studies of the effects of halogenated histidine analogs on Plasmodium falciparum.

The effects of four halogenated analogs of histidine on in vitro growth of Plasmodium falciparum malaria parasites were monitored by measurement of the incorporation of 3H-labeled amino acids into parasite proteins and by light and electron microscopy. The uptake of [3H]isoleucine was reduced to 50% of the control value by addition of 70 microM 2-fluoro-L-histidine (2-F-HIS) or 420 microM 2-iodo-L-histidine (2-I-HIS). [3H]histidine uptake into acid-insoluble material was affected equally by these two compounds, 50% inhibition resulting at 200 microM concentration. Morphological analysis of parasite development proved a sensitive assay, since development of mature trophozoites was inhibited 50% by 25 microM 2-F-HIS or 100 2-I-HIS. Electron microscopy studies suggested different mechanisms of action of 2-F-HIS and 2-I-HIS on P. falciparum. 2-F-HIS produced a decrease in knob number at the erythrocyte surface and accumulation of electron-dense material under the parasite membrane. 2-I-HIS had no obvious effect on knobs or electron-dense material but affected parasite morphology. Surprisingly, 2-chloro-L-histidine and 2-bromo-L-histidine did not inhibit P. falciparum in vitro, even though their halogen atom substituents are intermediate in size between F and I atoms. 2-F-HIS and 2-I-HIS were tested in vivo against P. falciparum in owl monkeys (Aotus sp.) but were ineffective at doses that were nontoxic.

Dissociation of the cardiovascular and prolactin-releasing activities of norvaline2-TRH.

The effects of thyrotropin-releasing hormone (TRH) and norvaline2-TRH (Nva2-TRH) on blood pressure, heart rate and plasma prolactin levels in conscious rats have been compared. Systemic injection of TRH or Nva2-TRH (1 mg/kg or 5 mg/kg) produced equipotent increases in plasma prolactin. On the other hand, while TRH significantly increases blood pressure and heart rate, Nva2-TRH was essentially inactive. Thus, two contrasting analogues are now available: 4-NO2-Im-TRH (Neuropeptides, 8, 63, 1986) has full cardiovascular activity and no PRL-releasing activity, while Nva2-TRH has no cardiovascular activity and full PRL-releasing activity of TRH.

Effect of thyrotropin releasing hormone and some of its histidine analogs on the cardiovascular system and prolactin release in the conscious rat.

The cardiovascular and endocrine activity of three analogs of thyrotropin releasing hormone (TRH), 4-nitro-imidazole TRH (4-nitro-TRH), 2-trifluoro-methyl-imidazole TRH (2-TFM-TRH) and 4-trifluoro-methyl-imidazole TRH (4-TFM-TRH), was compared to TRH in conscious rats. Injection of TRH or the three analogs (1 mg/kg or 5 mg/kg) into the arterial line induced increases in mean arterial pressure, pulse pressure and heart rate and raised plasma prolactin (PRL). None of the analogs were more potent than TRH in inducing cardiovascular changes. The 4-TFM-TRH was significantly less potent than the 2-TFM-TRH in increasing blood pressure, while the nitro-TRH was more potent than the 2-TFM-TRH in producing tachycardia. TRH induced a two-fold increase in PRL at the 5 mg/kg dose, while both the fluorinated analogs elicited a 4 to 5 fold increase in PRL at the higher dose. The present results suggest that the receptors for TRH-elicited PRL release differ from TRH-receptors involved in its cardiovascular actions.

Differential effect of fluorinated analogs of TRH on the cardiovascular system and prolactin release.

The effects of thyrotropin-releasing hormone (TRH) and the TRH-analogs, 4-fluoro-Im-TRH (4-F-TRH) and 2-trifluoromethyl-Im-TRH (2-TFM-TRH), on the cardiovascular system and prolactin (PRL) release were examined in conscious rats. TRH (2.8 or 28 nmol) injected into the anterior hypothalamus produced dose-dependent increments in blood pressure and heart rate; plasma PRL was increased twofold after the higher dose of TRH. 4-F-TRH had effects similar to those of TRH on both the cardiovascular and PRL response. In contrast, the 2-TFM-TRH was significantly less active than TRH or 4-F-TRH in eliciting tachycardia, yet was noticeably more potent in affecting PRL release. These data suggest that the receptors for TRH-induced PRL release may be different from TRH-receptors which mediate central cardiovascular responses.

Synthesis and biological activity of 5-fluoroimidazole-TRH.

The 5-fluoroimidazole analogue of thyrotropin-releasing hormone, obtained by total synthesis from 5-fluoro-L-histidine, neither binds to rat pituitary cells nor stimulates release of prolactin from them. Lévine-Pinto et. al. reported an agonist, which was generated during presumptive photofluorination of the hormone and which they believed to be the 5-fluoro analogue. In addition to the striking contrast in biological activities, the chemical properties of the agonist differ markedly from those of our peptide and are inconsistent with expectation for the fluoroimidazole moiety. Despite its inactivity in pituitary functions, the authentic 5-fluoro analogue mimics the natural hormone with respect to cardiovascular responses in the central nervous system.