In situ hybridization localization of TRH precursor and TRH receptor mRNAs in the brain and pituitary of Xenopus laevis.

We examined the distribution of the mRNAs encoding proTRH and the three TRH receptor subtypes (xTRHR1, xTRHR2, and xTRHR3) in the Xenopus laevis CNS and pituitary. A positive correlation was generally observed between the expression patterns of proTRH and xTRHR mRNAs. xTRHRs were widely expressed in the telencephalon and diencephalon, where two or even three xTRHR mRNAs were often simultaneously observed within the same brain structures. In the pituitary, xTRHR2 was selectively expressed in the distal lobe, and xTRHR3 was found exclusively in the intermediate lobe of white background-adapted animals, indicating that, in amphibians, the effect of TRH on alpha-melanotropin (alpha-MSH) secretion from melanotrope cells is mediated through the novel receptor subtype xTRHR3.

Cloning of thyrotropin-releasing hormone precursor and receptor in rat thymus, adrenal gland, and testis.

TRH is a hypophysiotropic peptide that acts mainly via the hypothalamic-pituitary-thyroid axis, but TRH immunoreactivity is also detected in several peripheral tissues. PCR with two pairs of primers enabling amplification of three fragments of TRH complementary DNA (cDNA) was used to demonstrate local production of TRH. Products of the expected size were detected in the testis, adrenal gland, lymphoid organs, thymus, and spleen. The amplified cDNA fragments were cloned and sequenced to show that the TRH gene is expressed in the thymus, spleen, and adrenal gland. Competitive RT-PCR showed that the TRH messenger RNA content of the testis was about one third that of the hypothalamus, whereas the adrenal gland contained 2% and the thymus 6%. HPLC analysis of thymus and spleen extracts showed small amounts of TRH, with a particular processing pattern of pro-TRH in lymphoid organs. The expression of the TRH receptor gene in peripheral organs was investigated to determine whether TRH had an autocrine or a paracrine action. cDNA fragments that encompassed the coding region of the receptor were identified in the testis, adrenal gland and thymus. No signal was detected in the spleen. These findings indicate that TRH may have a biological activity in extrapituitary organs and may act locally in the testis, adrenal gland, and thymus.

Specific binding sites for rat prepro-TRH-(160-169) on C6 glioma and BN1010 clonal neural cells.

A connecting decapeptide corresponding to rat prepro-TRH-(160-169) (Ps4) displays several biological activities that are related or unrelated to TRH. We have previously characterized pituitary binding sites for this connecting peptide and elucidated structural determinants for high peptide binding affinity. In the current study, a series of cell lines was screened for the presence of specific binding sites with a highly potent derivative of Ps4, the monoiodinated radioligand [125I-Tyr0]Ps4. Neuroblastoma x glioma hybrid NG108-15, glioma C6 and neuroblastoma BN1010 cell lines were found to have high-affinity [125I-Tyr0]Ps4 binding sites containing 600, 9700 and 130000 sites/cell, respectively. The specific binding of [125I-Tyr0]Ps4 was rapid, time-dependent, reversible and proportional to the amount of C6 and BN1010 membrane preparation. Furthermore, Scatchard or Hill analysis revealed that [125I-Tyr0]Ps4 was bound by a single population of non-interacting sites with dissociation constants in the subnanomolar range. Competition studies made with Ps4 analogues indicated that [125I-Tyr0]Ps4 binding sites on C6 and BN1010 cells were similar to those previously described on rat pituitary membranes. It is concluded that C6 and BN1010 cells are suited for studies on the intracellular events following binding of the Ps4 and for the molecular characterization of the Ps4 binding sites.

Thyrotropin-releasing hormone immunoreactivity in rat adrenal tissue is localized in mast cells.

Pro-thyrotropin-releasing hormone (pro-TRH) has been shown to be present throughout the central nervous system and in several peripheral tissues. In adrenals, TRH immunoreactivity has been reported but not characterized. We show here that two rat pro-TRH-derived peptides, TRH and prepro-TRH[160-169] (Ps4), were detected in extracts of rat adrenal glands by enzyme immunoassay. Endogenous TRH and Ps4 were purified by gel exclusion chromatography and reverse-phase HPLC. Structural identification of each peptide was achieved by chromatographic comparison with synthetic standards. By using the indirect immunofluorescence technique, TRH-immunoreactive cell bodies were found rather widely scattered outside the adrenal, in the brown adipose tissue in which the gland is embedded. These immunofluorescent cells have the typical appearance of mast cells and are metachromatic after histological staining with acidic Toluidine Blue. Our findings suggest that pro-TRH-derived peptides exist in rat mast cells.

Identification and cellular localization of thyrotropin-releasing hormone-related peptides in rat testis.

Endogenous TRH-like products were analyzed in rat testis using a TRH enzyme immunoassay coupled to molecular sieve filtration and HPLC identification. Of the three immunoreactive peptides detected, the two major forms exhibited the same chromatographic properties as synthetic TRH and pGlu-Phe-Pro-NH2. These peptides accounted respectively for 33% and 54% of the total TRH immunoreactivity in the testis. In rat serum, HPLC analysis showed the presence of only one immunoreactive peak with a retention time similar to that of authentic TRH. Ethylene dimethanesulfonate treatment of adult rat was used to assess the effect of Leydig cell destruction on the TRH immunoreactivity content. The concentration of the three TRH immunoreactive peptides fell gradually after treatment and reached a minimum at day 21, where a marked decrease (98%) was observed. At day 41, the regeneration of Leydig cells was achieved, as shown by histochemistry and measurements of serum testosterone and testicular weight. However, no restoration of the TRH immunoreactive content was achieved, the three TRH-related peptides being only detectable in trace amount. On the other hand, no significant change in hypothalamic levels of TRH was observed at any treatment time, indicating that hypothalamic TRH biosynthesis was not influenced by testosterone. By using the indirect immunofluorescence technique, TRH immunoreactive cells were found in the interstitial space of the testis. These results suggest that Leydig cells are the only source of authentic TRH and TRH-like peptides in the rat testis. A paracrine, or autocrine role for these products is suggested.

Distribution of TRH-potentiating peptide (Ps4) and its receptors in rat brain and peripheral tissues.

TRH-potentiating peptide (Ps4) is a peptide originally isolated from bovine hypothalamus, which corresponds to the deduced rat prepro-TRH-(160-169) sequence. We have examined the distribution of Ps4 and [125I-Tyr0]Ps4 binding sites in various rat tissues. Very high specific binding of [125I-Tyr0]Ps4 was observed in pituitary membranes. Almost identical relative magnitude of binding was found in spinal cord, hypothalamus, hippocampus and olfactory lobe. In addition, a high density of Ps4 binding sites was demonstrated in urogenital organs. The observed distribution pattern of Ps4 in brain tissues was similar to that reported for TRH, with high concentrations in the hypothalamus and significant amount in spinal cord and olfactory lobe. These findings support the hypothesis that the TRH-potentiating peptide could act as neuromodulator or neurotransmitter in the central nervous system (CNS). In peripheral tissues, very low concentrations of Ps4 were detected except in testis which seems to be the major locus for Ps4 biosynthesis. This study demonstrated for the first time that TRH-potentiating peptide and its receptors are widely distributed in the CNS and peripheral tissues.

Modulation of the biological activity of thyrotropin-releasing hormone by alternate processing of pro-TRH.

Thyrotropin-releasing hormone prohormone contains multiple copies of TRH linked together by connecting sequences. Like other plurifunctional prohormone proteins, pro-TRH undergoes differential proteolytic processing in various tissues to generate, beside authentic TRH, several other novel peptides corresponding to C-terminally extended forms of TRH and connecting fragments. The pro-TRH connecting peptides are, together with TRH, predominant storage forms of TRH-precursor related peptides in the rat hypothalamus. Connecting peptides are co-localized with TRH in the median eminence nerve endings and co-released through a mechanism involving voltage-operated Ca2+ channels. The connecting peptide Ps4 is involved in potentiation of the action of TRH on thyrotropin hormone release by pituitary in vitro and in vivo through interactions with a specific pituitary cell receptor coupled to dihydropyridine and omega-connotoxin sensitive Ca2+ channels of the L-type. It also causes dose-dependent increases in the steady state levels of mRNAs of TSH and prolactin through stimulation of the respective gene promoter activities. These findings indicate that Ps4 and TRH, two peptides which originate from a single multifunctional biosynthetic precursor, can function on the same target tissues in a coordinate manner to promote hormonal secretion. This suggests that differential processing of the TRH prohormone may have the potential to modulate the biological activities of TRH.

Analysis of structural requirements for TRH-potentiating peptide receptor binding by analogue design.

Previous studies established that the [125I-Tyr0]Ps4 derivative of TRH-potentiating peptide (Ps4), Ser-Phe-Pro-Trp-Met-Glu-Ser-Asp-Val-Thr, displays high affinity and selectivity for an orphan membrane receptor in rat anterior pituitary. To identify the sites in Ps4 that determine receptor binding affinity, we have synthesized and screened a panel of 15 single-point substituted analogues for their ability to displace bound [125I-Tyr0]Ps4. The affinity of [Tyr0]Ps4 for rat anterior pituitary membranes [inhibitory constant (Ki), approximately 5 nM] was drastically reduced by the substitution of either Tyr0 with Gly or Asp8 with Asn (Ki approximately 95 and approximately 51 nM, respectively). Deamination of [Tyr0]Ps4 also sharply reduced affinity (Ki approximately 1100 nM). In contrast, Ser1-->Ala, Pro3-->Ala and Thr10-->Val substitutions led to analogues showing a tenfold increase in binding affinity relative to the parent peptide. The change of Phe2-->Leu, Trp4-->Ala, Glu6-->Gln, Val9-->Thr and carboxamidation of Thr10 had no effect on binding affinity. The data suggest that substitutions of the amino-terminal group, Asp8 and Tyr0, have a marked effect on the ability of [Tyr0]Ps4 to compete with [125I-Tyr0]Ps4 for binding to TRH-potentiating peptide pituitary receptor.

Isolation and amino acid sequence of the TRH-potentiating peptide from bovine hypothalamus.

A neuropeptide termed TRH-potentiating peptide, which potentiates TRH-evoked thyrotropin secretion by antehypophysis in vitro, was isolated from an acetonic powder of bovine hypothalamus. The peptide was purified to homogeneity by a 3-step protocol involving molecular sieve filtration, ion-exchange chromatography and reverse phase high performance liquid chromatography. The complete amino acid sequence of the decapeptide was determined as Ser-Phe-Pro-Trp-Met-Glu-Ser-Asp-Val-Thr by automated Edman degradation with a solid-phase sequencer. Bovine TRH-potentiating peptide is structurally identical to Ps4, a decapeptide which was deduced from the cDNA encoding the rat TRH precursor. This study provides for the first time a direct chemical evidence for the existence of non-TRH peptides originating from posttranslational processing of the TRH precursor in vivo.

Characterization of receptors for thyrotropin-releasing hormone-potentiating peptide on rat anterior pituitary membranes.

Previous studies (Bulant, M., Delfour, A., Vaudry, H., and Nicolas, P. (1988) J. Biol. Chem. 263, 17189-17196; Bulant, M., Roussel, J. P., Astier, H., Nicolas, P., and Vaudry, H. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 4439-4443) have shown that post-translational processing of rat thyrotropin-releasing hormone prohormone (pro-TRH) generates, besides thyrotropin-releasing hormone (TRH), a connecting decapeptide corresponding to prepro-TRH-(160-169), i.e. Ser-Phe-Pro-Trp-Met-Glu-Ser-Asp-Val-Thr. This peptide, which is named TRH-potentiating peptide (Ps4), is co-localized with TRH in the median eminence nerve endings and is involved in potentiation of the action of TRH on thyrotropin hormone release by pituitary in vitro and in vivo. To characterize the receptor(s) for TRH-potentiating peptide in the pituitary, a highly potent and metabolically stable derivative of Ps4, [I-Tyr0]Ps4, was radioiodinated. Binding of [125I-Tyr-0]Ps4 to rat pituitary membrane homogenates was specific, saturable, reversible, and linear with membrane protein concentration. Equilibrium measurements performed over a large range of concentrations revealed a single homogeneous population of high affinity binding sites (Kd = 0.22 nM; Bmax = 517 fmol/mg of membrane proteins). Several naturally occurring neuropeptides and hormones, including TRH, did not compete with [125I-Tyr0]Ps4 in the binding, which suggests the binding sites are specific to Ps4. Using C-terminal deletion analogs of [Tyr0]Ps4, we further showed the critical role the C-terminal residues Thr10, Val9, and Asp8 play in conferring high binding affinity and selectivity. Binding site tissue distribution and cross-reactivity binding studies suggest that the action of TRH-potentiating peptide is mediated through interaction with a specific pituitary cell-surface receptor which differ from those for TRH. [I-Tyr0]Ps4 reported in this paper, through its high binding affinity and specificity, its very low nonspecific binding, its high resistance to enzymatic degradation, and its high potentiating action in vitro should allow further progress in understanding the in vivo physiological function of Ps4.

Pattern of thyrotropin-releasing hormone secretion from the adult and neonatal rat pancreas: comparison with insulin secretion.

In the present study we examined the secretory pattern of pancreatic TRH. TRH is synthesized in the islets of Langerhans as a high mol wt prohormone, which is then processed to give TRH and several putative pro-TRH fragments. The mature TRH was localized in insulin-containing cells of developing rat pancreas, marked by elevated TRH concentrations. The biological role of pancreatic TRH in the regulation of major pancreatic hormones secretion is still poorly understood. We, therefore, studied TRH release from isolated perfused rat pancreas and from neonatal and adult islets in the absence and presence of glucose and arginine to investigate regulation of TRH secretion compared to that of insulin secretion. The secretory pattern of TRH was the opposite of that of insulin in adult pancreas, but was similar to that of insulin in the developing pancreas, suggesting the presence of a subpopulation of beta-cells with peculiar age-dependent topololgy and/or different intracellular transport for TRH. Additionally, antibodies to two pro-TRH-connecting peptides, pro-TRH-(160-169) and pro-TRH-(178-199), were used to characterize the processing in the developing and the adult rat pancreas. There were parallel age-dependent decreases in TRH and both connecting peptides. Interestingly enough, only pro-TRH-(178-199) was selectively released, suggesting that some of the pro-TRH fragments may also assume biological effects. The establishment of these parameters will allow appropriate screening of the biological response to TRH.

A cDNA from brain of Xenopus laevis coding for a new precursor of thyrotropin-releasing hormone.

Thyrotropin-releasing hormone (TRH) is found in large amounts in the skin of Xenopus laevis. In this tissue, 3 TRH precursor mRNAs can be detected of which the 2 more expressed encode almost identical proteins. However, Northern blot analysis of TRH precursor mRNAs in the brain of X. laevis revealed the existence of a new mRNA of about 1200 nucleotides which was present along with the larger TRH precursor mRNA identified in the skin. A cloned cDNA of a TRH precursor, corresponding in size to this new mRNA, was isolated and sequenced from a Xenopus brain lambda gt11 library. It encodes a precursor polypeptide which also contains 7 copies of TRH. However, at the amino acid level it differs by about 16% from the corresponding prepro-TRHs from skin. We have also attempted to characterize the gene encoding this prepro-TRH from Xenopus brain. Only the first and part of the second exon could be detected which are separated by an intron containing more than 8000 base pairs. Interestingly, the 5'-flanking region of this gene does not contain the characteristic promoter elements of the mammalian TRH genes suggesting marked differences in the regulation of their expression.

A prepro-TRH connecting peptide (prepro-TRH 160-169) potentiates TRH-induced TSH release from rat perifused pituitaries by stimulating dihydropyridine- and omega-conotoxin-sensitive Ca2+ channels.

The stimulation of TSH secretion by TRH involves the phosphatidylinositol second messenger pathway via activation of phospholipase C. This effect is mediated by a GTP-binding protein and leads to a mobilization of intracellular Ca2+ stores and an activation of protein kinase C. However, TRH stimulation also results in an influx of extracellular Ca2+. Since we have previously demonstrated that a non-TRH fragment of the prepro-TRH molecule, the connecting peptide PS4 (prepro-TRH 160-169), was able to potentiate the TRH-induced TSH release in a dose-dependent manner, we attempted to determine whether this potentiation might be due to a Ca(2+)-dependent phenomenon and whether a specific class of voltage-dependent Ca2+ channels, the L type Ca2+ channels, might be involved in the effect of PS4. This was studied by perifusing normal pituitary fragments with medium containing either the Ca2+ ionophore, ionomycin, and Co2+ ions, or organic compounds well known to block L-type Ca2+ channels, and by measuring the TSH response to a pulse of TRH (10 nM) in the presence or absence of PS4 (100 nM).(ABSTRACT TRUNCATED AT 250 WORDS)

Anatomical interactions of proopiomelanocortin (POMC)-related peptides, neuropeptide Y (NPY) and dopamine beta-hydroxylase (D beta H) fibers and thyrotropin-releasing hormone (TRH) neurons in the paraventricular nucleus of rat hypothalamus.

In order to determine the nature of afferent fibres contacting thyrotropin-releasing hormone (TRH)-synthesizing neuronal cell bodies in the rat hypothalamic paraventricular nucleus, we used dual immunostaining procedures which employed antibodies to ACTH (to label proopiomelanocortin (POMC) neurons), neuropeptide Y (NPY) and dopamine-beta-hydroxylase (D beta H) and peroxidase-labeled goat anti-rabbit IgG as a first sequence and antibodies to a cryptic fragment (Phe178-Glu199) of pro-TRH (to label TRH neurons) and alkaline phosphatase-labeled goat anti-rabbit IgG as the second sequence. A rich innervation of the paraventricular nucleus by immunoreactive POMC, NPY and D beta H fibres was observed. Numerous NPY and POMC fibres were in intimate anatomic proximity and often appeared to surround in remarkable density TRH-containing cell bodies. Less frequent appositions between D beta H fibres and TRH cell bodies were detected. These results strongly suggest that TRH neurons might be regulated by POMC, NPY as well as adrenergic and/or noradrenergic systems. These interactions might be the neuroanatomical basis for the already observed effects of opiate peptides, NPY and catecholamines on TSH secretion.

Processing of thyrotropin-releasing hormone (TRH) prohormone in the rat olfactory bulb generates novel TRH-related peptides.

Based on the deduced amino acid sequence of rat TRH prohormone (pro-TRH), proteolytic processing of this polyprotein precursor is expected to produce, beside TRH, several other novel peptides. These peptides should correspond to connecting segments flanking the repeated TRH progenitor sequence and to various C- and/or N-terminally extended forms of TRH. The profile of the endogenous products of the TRH system was studied in rat brain using multiple RIAs coupled to molecular sieve filtration and HPLC separations. In extracts from the rat hypothalamus, TRH and two pro-TRH-connecting peptides, prepro-TRH-(160-169) and prepro-TRH-(178-199) were detected in molar ratios corresponding to those expected for a nearly complete processing of the prohormone molecule. In the olfactory bulb, pro-TRH is processed differently, since peptides containing TRH at their N-termini, [pGlu172] prepro-TRH-(172-199) and [pGlu154]prepro-TRH-(154-169), were found to be major end products along with prepro-TRH-(160-169) and prepro-TRH-(178-199). The dissimilarity in tissue content suggests that differential processing of TRH precursor by various enzymatic pathways may act as a regulating mechanism for TRH and TRH-related activities. The cellular localization of C-terminally extended forms of TRH in rat olfactory bulb was examined by the indirect immunoperoxidase method, using antisera directed against prepro-TRH-(160-169) and pre-pro-TRH-(178-199). Cell bodies and nerve fibers were detected in the glomerular and external plexiform layers of the main olfactory bulb. The presence of extended forms of TRH in interneurons and middle tufted cells of the main olfactory bulb suggests that in light of the recent biological properties described for prepro-TRH-(160-169), these peptides may act as neuromodulators for olfactory epithelium inputs or neurotransmitters within more rostrally located olfactory areas in the forebrain.

Processing of thyrotropin-releasing hormone prohormone (pro-TRH) generates a biologically active peptide, prepro-TRH-(160-169), which regulates TRH-induced thyrotropin secretion.

Rat thyrotropin-releasing hormone (TRH) prohormone contains five copies of the TRH progenitor sequence Gln-His-Pro-Gly linked together by connecting sequences whose biological activity is unknown. Both the predicted connecting peptide prepro-TRH-(160-169) (Ps4) and TRH are predominant storage forms of TRH precursor-related peptides in the hypothalamus. To determine whether Ps4 is co-released with TRH, rat median eminence slices were perifused in vitro. Infusion of depolarizing concentrations of KCl induced stimulation of release of Ps4- and TRH-like immunoreactivity. The possible effect of Ps4 on thyrotropin release was investigated in vitro using quartered anterior pituitaries. Infusion of Ps4 alone had no effect on thyrotropin secretion but potentiated TRH-induced thyrotropin release in a dose-dependent manner. In addition, the occurrence of specific binding sites for 125I-labeled Tyr-Ps4 in the distal lobe of the pituitary was demonstrated by binding analysis and autoradiographic localization. These findings indicate that these two peptides that arise from a single multifunctional precursor, the TRH prohormone, act in a coordinate manner on the same target cells to promote hormonal secretion. These data suggest that differential processing of the TRH prohormone may have the potential to modulate the biological activity of TRH.

Immunoelectron microscopic localization of thyrotropin-releasing hormone (TRH) precursor in the rat raphe nuclei.

Using antisera to two pro-thyrotropin-releasing hormone (pro-TRH)-derived cryptic peptides, we have studies by immunocytochemistry the ultrastructural localization of pro-TRH in the rat raphe nuclei. The same results were obtained with both antisera. Immunostaining was found in cell bodies, dendrites and endings. In cell bodies, the reaction product was restricted to Golgi saccules and dense core vesicles which were very few in number. In dendrites, the staining was rather diffuse without any association with specific organelles. These results suggest that the Golgi apparatus might be involved in pro-TRH processing.

Processing of thyrotropin-releasing hormone prohormone (pro-TRH) in the adult rat pancreas: identification and localization of pro-TRH-related peptides in beta-cells of pancreatic islets.

Rat TRH prohormone (pro-TRH) contains five separate copies of the TRH progenitor sequence, Gln-His-Pro-Gly. All five sequences are flanked by paired basic amino acid cleavage sites and linked together by connecting sequences. RIAs to synthetic TRH and prepro-TRH-(178-199) were used to investigate pro-TRH processing in the endocrine pancreas of adult rats. HPLC analysis of adult rat pancreatic extracts showed the presence of a major immunoreactive peptide eluting at the position of prepro-TRH-(178-199). An additional peak coeluting with [less than Glu172]prepro-TRH-(172-199) (less than Glu = pyroglutamyl) revealed the presence of a C-terminally extended form of TRH. Quantification of TRH in pancreatic extracts indicated the presence of 22 mol TRH/mol prepro-TRH-(178-199) and 17 mol TRH/mol [less than Glu172]prepro-TRH-(172-199). Treatment of rats with streptozotocin markedly reduced the pancreatic content of both immunoreactive TRH (-84%) and immunoreactive prepro-TRH-(178-199) (-62%). Light microscopic immunocytochemistry showed that prepro-TRH-(178-199)-like immunoreactivity was exclusively located within insulin-containing cells of the pancreatic islets. At the electron microscopic level, prepro-TRH-(178-199) immunoreactivity appeared to be concentrated in secretory granules. The present study demonstrates that processing of pro-TRH generates both non-TRH- and TRH-related peptides in the adult rat pancreas. Our data also indicate that beta-cells of the endocrine pancreas are the major source of TRH- and pro-TRH-derived peptides.

Thyroid hormone regulation of neurons staining for a pro-TRH-derived cryptic peptide sequence in the rat hypothalamic paraventricular nucleus.

The influence of thyroid hormones on neurons staining for a pro-TRH-derived cryptic peptide sequence in the rat hypothalamic paraventricular nucleus was assessed by using quantitative immunocytochemistry. The antiserum used for immunocytochemical studies recognized a cryptic fragment of pro-TRH located in the Phe 178-Ser 186 region of the precursor. Hypothyroid female rats obtained following 1 month administration of 6-n-propyl-2-thiouracil (PTU) as well as euthyroid animals were treated with a low (3 micrograms/kg/day) or high (67 micrograms/kg/day) dose of L-thyroxine (T4) for 4-10 days before sacrifice. All the animals received an intraventricular injection of colchicine 2 days prior to perfusion with 4% paraformaldehyde. PTU treatment induced an increase (45% over control) in the number of immunostained neurons. The administration of a low dose of T4 to hypothyroid animals slightly increased the number of staining for a pro-TRH-derived cryptic sequence neurons, while being uneffective in euthyroid rats. In hypothyroid animals, a 4-day treatment with the high dose of T4 did not produce any changes whereas the 7-day treatment reduced the number of positive cells to 42% of control. In euthyroid rats treated with the high dose of T4 for 4 and 7 days, the number of stained neurons was reduced to 60 and 37% of control, respectively. These results indicate that thyroid hormones can modify the amounts of staining for a pro-TRH-derived cryptic sequence in hypothalamic paraventricular neurons.(ABSTRACT TRUNCATED AT 250 WORDS)