Effect of preproTRH antisense on thyrotropin-releasing hormone synthesis and viability of cultured rat diencephalic neurons.

To investigate a possible neurotropic role for thyrotropin-releasing hormone (TRH) in the central nervous system, we used recombinant antisense TRH adenovirus (TRHav) to "knock out" TRH in cultured 17-d fetal rat diencephalon. The morphology along with beta-galactosidase (beta-gal) enzyme histochemistry (X-gal staining) and TRH content (femtomoles/well) were used to measure the effect of antisense TRH virus. Control adenovirus mediated beta-gal transfection efficiency was nearly 85%, as shown by positive X-gal staining, and was without effect on cell morphology, TRH content, or the normal response to glucocorticoid (dexamethasone) exposure with enhanced TRH expression. A significant 90% decline in TRH content as well as changes in neuronal morphology (shrunken cell bodies and short dendrites) were observed after 14 but not 7 d following TRHav treatment. The addition of synthetic TRH peptide at 2.5 microM along with TRHav, but not dexamethasone, partly prevented the morphologic changes. No morphologic changes were seen in wild-type AtT20 cells, a pituitary cell line that does not produce TRH. To investigate whether neuronal death from loss of proTRH was owing to apoptosis, neuronal DNA change by means of fluorescent dye H-33342 staining, TUNEL staining, and DNA laddering analysis was examined. Eighty to 90% positive H-33342 and TUNEL staining as well as a 180- to 200-bp DNA fragment on DNA laddering analysis were found as compared to control. These results indicate that proTRH gene expression prevents neuronal apoptosis and may play a role in neuronal development and function.

Association of cocaine- and amphetamine-regulated transcript-immunoreactive elements with thyrotropin-releasing hormone-synthesizing neurons in the hypothalamic paraventricular nucleus and its role in the regulation of the hypothalamic-pituitary-thyroid axis during fasting.

Because cocaine- and amphetamine-regulated transcript (CART) coexists with alpha-melanocyte stimulating hormone (alpha-MSH) in the arcuate nucleus neurons and we have recently demonstrated that alpha-MSH innervates TRH-synthesizing neurons in the hypothalamic paraventricular nucleus (PVN), we raised the possibility that CART may also be contained in fibers that innervate hypophysiotropic thyrotropin-releasing hormone (TRH) neurons and modulate TRH gene expression. Triple-labeling fluorescent in situ hybridization and immunofluorescence were performed to reveal the morphological relationships between pro-TRH mRNA-containing neurons and CART- and alpha-MSH-immunoreactive (IR) axons. CART-IR axons densely innervated the majority of pro-TRH mRNA-containing neurons in all parvocellular subdivisions of the PVN and established asymmetric synaptic specializations with pro-TRH neurons. However, whereas all alpha-MSH-IR axons in the PVN contained CART-IR, only a portion of CART-IR axons in contact with pro-TRH neurons were immunoreactive for alpha-MSH. In the medial and periventricular parvocellular subdivisions of the PVN, CART was co-contained in approximately 80% of pro-TRH neuronal perikarya, whereas colocalization with pro-TRH was found in <10% of the anterior parvocellular subdivision neurons. In addition, >80% of TRH/CART neurons in the periventricular and medial parvocellular subdivisions accumulated Fluoro-Gold after systemic administration, suggesting that CART may serve as a marker for hypophysiotropic TRH neurons. CART prevented fasting-induced suppression of pro-TRH in the PVN when administered intracerebroventricularly and increased the content of TRH in hypothalamic cell cultures. These studies establish an anatomical association between CART and pro-TRH-producing neurons in the PVN and demonstrate that CART has a stimulatory effect on hypophysiotropic TRH neurons by increasing pro-TRH gene expression and the biosynthesis of TRH.

Evidence from studies with N-ethyl-maleimide and 12-O-tetradecanoylphorbol-13-acetate that AP-1 and CREB are involved in the glucocorticoid activation of TRH gene expression in hypothalamic cultures.

To determine whether c-fos/c-jun (AP-1) and CREB mediate glucocorticoid stimulated TRH gene regulation, we investigated the effect of N-ethyl-maleimide (NEM), an alkylating agent, and 12-O-tetradecanoylphorbol-13-acetate (TPA) on this process. NEM decreased while TPA increased TRH levels in rat hypothalamic culture, changes similar to their effects on CREB and Fos/Jun proteins in the AtT20 cell line. This suggests that glucocorticoid stimulation of TRH gene expression may be regulated by the AP-1 complex and CREB pathway.

Advantage of double labeled in situ hybridization for detecting the effects of glucocorticoids on the mRNAs of protooncogenes and neural peptides (TRH) in cultured hypothalamic neurons.

In order to study the effect of glucocorticoids on thyrotropin-releasing hormone (TRH) and protooncogenes, we describe a double labeled in situ hybridization method to explore this issue. The development of non-isotopic in situ hybridization histochemistry has proven to be an important tool for cellular and molecular studies in neurobiology [C.L.E. Moine, E. Normand, B. Bloch, Use of non-radioactive probes for mRNA detection by in situ hybridization: interests and applications in the central nervous system, Cell. Mol. Biol. 41 (1995) 917-923]. These methods involve the anatomic localization of labeled RNA or DNA molecules which hybridize with complementary target RNA or DNA sequences in the cell. With regard to gene expression, in situ hybridization allows the study of specific mRNA levels and the distribution between various cell types. It also allows the comparison of mRNA levels at various stages of development. Double labeled in situ hybridization is able to detect the colocalization of two different mRNAs simultaneously. Accordingly, this approach is utilized for specific studies involving the expression and distribution of TRH mRNA and the protooncogenes, c-fos/c-jun, in cultured rat hypothalamic neurons [L. G. Luo, I.M.D. Jackson, Glucocorticoids stimulate TRH and c-fos/c-jun gene co-expression in cultured hypothalamic neurons, Brain Research 791 (1998) 56-62]. Our protocol for double labeled in situ hybridization reflects a modification of a number of original protocols developed by others [H. Breitschopf, G. Suchanek, R.M. Gould, D.R. Colman, H. Lassmann, In situ hybridization with digoxigenin-labeled probes: sensitive and reliable detection method applied to myelinating rat brain, Acta Neurropathol. 84 (1992) 581-587; S. McQuaid, J. McMahon, G.M. Allan, A comparison of digoxigenin and biotin labeled DNA and RNA probes for in situ hybridization, Biotech. Histochem. 70 (1995) 147-154; E. Hrabovszky, M.E. Vrontakis, S.L. Petersen, Triple-labeling method combining immunocytochemistry and in situ hybridization histochemistry: demonstration of overlap between Fos-immunoreactive and galanin mRNA-expressing subpopulations of luteinizing hormone-releasing hormone neurons in female rats, J. Histochem. Cytochem. 43 (1995) 363-370]. This technique can be readily applied to various studies of cellular gene expression in the mammalian nervous system involving other neural peptides and transcription factors.

Antidepressants inhibit the glucocorticoid stimulation of thyrotropin releasing hormone expression in cultured hypothalamic neurons.

BACKGROUND: The pituitary thyroid axis is frequently effected in human depression possibly due to alteration in hypothalamic thyrotropin releasing hormone (TRH) secretion. Since clinical recovery is associated with normalization of thyroid function, the direct effect of antidepressants on TRH expression in a well established fetal rat hypothalamic neuronal culture system was investigated. METHODS: Fetal rat hypothalamic neurons (day 17) in culture were treated with different concentrations of antidepressants with or without glucocorticoids for 7 days following which TRH content was measured by radioimmunoassay (RIA). RESULTS: The results showed that Imipramine (IMIP), a tricyclic antidepressant (TCA), decreased the TRH content in a dose-dependent manner (from 80.7 +/- 4.9, at 10(-9) mol/L, to 14.1 +/- 0.6, at 10(-5) mol/L, fmol/well; P < 0.05). Desipramine (DESI), another tricyclic antidepressant, also decreased the TRH content (from 63.6 +/- 2.5, at 10(-9) mol/L, to 12.6 +/- 0.4, at 10(-5) mol/L, fmol/well; P < 0.05). Sertraline (SERT) and Fluoxetine (FLUO), serotonin selective reuptake inhibitors (SSRI), also decreased TRH content in a dose dependent manner (from 83.9 +/- 7.9, at 10(-10) mol/L, to 7.6 +/- 0.4, at 10(-5) mol/L, and from 41.66 +/- 2.5, at 10(-8) mol/L, to 17.54 +/- 0.92, at 10(-6) mol/L, fmol/well, respectively; both P < 0.05). We then tested the effect of these antidepressants on the Dex stimulation of TRH content. IMIP, DESIP and FLUO at 10(-6) mol/L reduced the TRH response to glucocorticoid stimulation (36.4 +/- 4.0, 56.6 +/- 2.4, 23.75 +/- 4.0, respectively vs 107 +/- 7.5 fmol/well; P < 0.05). CONCLUSION: This raises the possibility that the enhanced thyroid function in depression, which we postulate, may result in part from glucocorticoid stimulation of TRH gene expression, can be reversed by antidepressants through a direct effect on the TRH neuron. However, other mechanisms may need to be invoked in addition since basal TRH content was also reduced.

Glucocorticoids stimulate TRH and c-fos/c-jun gene co-expression in cultured hypothalamic neurons.

To explore whether the protooncogenes, c-fos/c-jun, might be involved in regulating the effect of glucocorticoids on thyrotropin-releasing hormone in fetal rat diencephalic neurons, their localization and transcriptional activity were investigated using double-labeled in situ hybridization, Northern blot and nuclear run-on assays. The results showed that TRH mRNA was coexpressed with both c-jun and c-fos in the same neurons. Treatment with dexamethasone, a synthetic glucocorticoid, at 10(-8) M, enhanced transcriptional activity resulting in an increase in both cell number and intensity of all three mRNAs. The existence of c-fos/c-jun in thyrotropin-releasing hormone neurons and the increased transcriptional activity following dexamethasone treatment suggests that these protooncogenes could mediate the effect of glucocorticoids on thyrotropin-releasing hormone gene expression.

Identification of the thyrotropin-releasing hormone precursor, its processing products, and its coexpression with convertase 1 in primary cultures of hypothalamic neurons: anatomic distribution of PC1 and PC2.

The processing of pro-TRH, has been extensively studied in our laboratory using a corticotropic cell line, AtT20, transfected with the pro-TRH gene. We have also demonstrated that the convertases PC1 and PC2 process pro-TRH to cryptic peptides in vitro. However, although these processing pathways have been well characterized in vitro, little is known about the processing and subcellular distribution of pro-TRH and its derived peptides in hypothalamic neurons, an endogenous source of pro-TRH and PC enzymes. In this study we used multiple approaches to identify, both biochemically and anatomically, the presence and localization of pro-TRH (26 kDa) and its processing products. We also investigated the presence of PC1 and PC2 enzymes and the coexpression of pro-TRH and PC1 messenger RNAs. Identification of the TRH precursor was demonstrated by 1) Western blot analysis of cellular extracts, 2) immunoprecipitation of radiolabeled pro-TRH followed by analysis on acrylamide gel electrophoresis, 3) fluorescence immunocytochemistry, and 4) immunoelectron microscopy. The presence of the convertases PC1 and PC2 was determined by Western blot analysis of cellular extracts and fluorescence immunocytochemistry. The coexpression of pro-TRH with PC1 was shown by double in situ hybridization. Our findings support three main conclusions. First, this primary culture system of hypothalamic neurons is suitable for characterizing pro-TRH processing as well as identifying the anatomical location of its processing products. Second, prohormome processing takes place during axonal transport after removal of the signal peptide in the endoplasmic reticulum, and subsequent cleavages of the prohormone occur as intermediate peptides move down the axon toward the nerve terminal. This coupled transport-processing phenomenon may provide the necessary mechanism to ensure flexibility in differential processing of specific protein sequences that are determined by the secretory needs of cells. It appears that certain intermediate peptides differ in their subcompartmental distribution, suggesting the possibility of a differential processing and maturation of pro-TRH-derived peptides. Thirdly, the 87-kDa form of PC 1 may initiate the processing of pro-TRH at the Golgi complex level, which then continues to be processed by PC1 and PC2 in later stages of the secretory pathway.

Glucocorticoids stimulate thyrotropin-releasing hormone gene expression in cultured hypothalamic neurons.

Although there is much evidence indicating that glucocorticoids (GC) inhibit the hypothalamic-pituitary-thyroid axis in both rat and man in vivo, there have been no previous studies on the direct effect of GC on hypothalamic TRH neurons in vitro. In this laboratory, we developed fetal rat (day 17) diencephalic neuronal cultures in the presence of 5'-bromo-2-deoxyuridine, a cell-differentiating agent that stimulates TRH gene expression. In 12 separate experiments, dexamethasone (Dex) induced a 2.2-fold increase in TRH content vs. the control value (P < 0.01). Dex (10(-8)M) enhanced TRH messenger RNA (mRNA) 1.6-fold (n = 75 wells; P < 0.01) by nonisotopic in situ hybridization. On Northern blot analysis using a 32P-labeled complementary RNA probe, TRH mRNA was enhanced 3-fold (n = 4; P < 0.01). Nuclear run-on analysis revealed that Dex enhanced transcription 7.7 fold (n = 3; P < 0.01). We conclude that 1) Dex stimulates the expression of TRH peptide and TRH mRNA in cultured hypothalamic neurons; 2) the increase in TRH mRNA results (at least in part) from enhanced transcription; and 3) the reported in vivo depression of TRH in the paraventricular nucleus after GC stimulation suggests that this effect must be mediated indirectly on the TRH neuron.

Processing of prothyrotropin-releasing hormone (Pro-TRH) by bovine intermediate lobe secretory vesicle membrane PC1 and PC2 enzymes.

TRH is synthesized from a larger 26-kilodalton (kDa) prohormone (pro-TRH). Rat pro-TRH contains five copies of the TRH progenitor sequence (Gln-His-Pro-Gly) and seven other cryptic peptides. Each of the five TRH progenitor sequences is flanked by pairs of basic amino acids. We used a bovine intermediate lobe secretory vesicle membrane preparation, which contains the prohormone convertases (PCs) PC1 and PC2, to study the in vitro processing of pro-TRH. Pro-TRH was radiolabeled using [3H]Leu in AtT20 cells transfected with prepro-TRH complementary DNA, and the labeled 26-kDa pro-TRH was isolated from the cell extract by preparative sodium dodecyl sulfate-gel electrophoresis. Incubation of [3H]pro-TRH with the intermediate lobe secretory vesicle membrane preparation was followed by immunoprecipitation with antibodies specific for various regions of the pro-TRH sequence, and the immunoprecipitates were analyzed by sodium dodecyl sulfate-gel electrophoresis. Immunoprecipitation of the reaction mixture with anti-pCC10 antibody (an antibody that recognizes the intact precursor and amino-terminal intermediate products of processing) showed a time-dependent appearance of a 15-kDa and a 6-kDa peptide and, at times, a 3.8-kDa peptide with diminution of the 26-kDa substrate. Immunoprecipitation of the incubate with the C-terminal-directed antibody, pYE17 (an antibody that recognizes the intact precursor and C-terminal intermediate products of processing), showed the generation of 16.5-, 10-, and 5.4-kDa products in a time-dependent manner, with disappearance of the substrate. Western blot analysis demonstrated that the secretory vesicle membrane preparation contains PC1 and PC2. Immunodepletion studies with antiserum specific for PC1 or PC2 demonstrated that PC1 and PC2 can process pro-TRH to these intermediate products. An initial site of cleavage appeared to be either at the 152-153 or the 158-159 pair of basic residues to yield a 15-kDa N-terminal fragment that was then processed to the 6-kDa [TRH-(25-74)] and 3.8-kDa [TRH-(83-112)] forms. The 10-kDa C-terminal peptide generated by this cleavage was then processed to a 5.4-kDa peptide [TRH-(208-255)]. Alternatively, an initial cleavage at the 107-108 or the 112-113 bonds was also observed, yielding a 16.5-kDa C-terminal product that was further processed to the 5.4-kDa peptide. The pH profile for the appearance of both C- and N-terminal products showed a bimodal distribution, with optima at both 5.5 and 7.5. The cleavage of pro-TRH was enhanced by Ca2+ and partially inhibited by Zn2+.(ABSTRACT TRUNCATED AT 400 WORDS)

Thyrotropin-releasing hormone gene expression in the anterior pituitary. II. Stimulation by glucocorticoids.

The present studies were undertaken to determine whether glucocorticoids (GC) regulate TRH gene expression in cultured anterior pituitary (AP) cells. AP cells derived from 15-day-old male rats were cultured for up to 18 days in Dulbecco's Modified Eagle's Medium-L-15 medium supplemented with 1) fetal calf serum (FCS), 2) charcoal-treated FCS, 3) normal rat serum, or 4) serum from rats that were adrenalectomized, rendered hypothyroid, and gonadectomized (ATG rat serum). Dexamethasone (Dex) or corticosterone (Cort) was added to the culture medium at various concentrations with exposure times ranging from 4-18 days. TRH and prepro-TRH-(25-50) in cellular extracts and release media were measured by RIA, and pro-TRH mRNA was determined by Northern blot analysis and in situ hybridization. Dex substantially stimulated cellular TRH and prepro-TRH-(25-50) accumulation under all culture conditions investigated, i.e. in medium supplemented with any of the four sera. TRH gene expression did not occur in medium supplemented with charcoal-treated FCS or ATG rat serum. Pretreatment with 10(-8) M Dex caused a significant increase in basal as well as cAMP- or phorbol ester-stimulated release of the peptide. Steady state pro-TRH mRNA levels rose 6.8- and 4.2-fold (both P < 0.01) after treatment with 10(-8) M Dex for 4 and 12 days, respectively. In situ hybridization experiments revealed that this rise in pro-TRH mRNA levels was probably the result of an increase in the number of AP cells expressing pro-TRH. Both Dex and Cort caused a dose-dependent increase in TRH accumulation, but Cort was approximately 40 times less potent than Dex. These results indicate that GC stimulate TRH gene expression in cultured AP cells. The presence of GC in culture medium is a prerequisite for the occurrence of TRH gene expression in the AP. As GC have been reported to reduce pro-TRH mRNA levels in the hypothalamus in vivo, our results may provide an example of the tissue-specific effects of GC on TRH gene expression.

Thyrotropin-releasing hormone gene expression in the anterior pituitary. III. Stimulation by thyroid hormone: potentiation by glucocorticoids.

The present study was designed to investigate the effect of thyroid hormone on TRH gene expression in cultured anterior pituitary (AP) cells. AP cells derived from 15-day-old male rats were cultured for up to 14 days in Dulbecco's Modified Eagle's Medium-L-15 medium supplemented with either fetal calf serum (FCS) or FCS devoid of thyroid hormones. T4 or T3 were added at various concentrations to the medium for a duration of 2-14 days. TRH and GH were measured by RIA, and pro-TRH mRNA levels were determined by semiquantitative in situ hybridization. Addition of both T3 and T4, but not the biologically inactive diiodothyronine, significantly stimulated TRH accumulation in AP cells. T3 increased TRH content in a time- and dose-dependent fashion and was much more potent than T4. Dexamethasone (Dex) also raised the content of TRH significantly. The combination of 10(-9) M T3 and 10(-8) M Dex dramatically potentiated the effect of either treatment alone (T3, 8.9-fold rise; Dex, 37.2-fold rise) and increased TRH accumulation 251.2-fold (all P < 0.01). Levels of pro-TRH mRNA mirrored TRH content data. T3, Dex, or the combination of both raised pro-TRH mRNA levels 1.9-, 2.7 (both P < 0.05)-, and 11.1 (P < 0.01)-fold, respectively. The visualization of pro-TRH mRNA by in situ hybridization revealed that the combination of T3 and Dex treatment caused a substantial increase in the number of cells expressing pro-TRH. The results presented here demonstrate that T3 increases pro-TRH gene expression in cultured AP cells and that glucocorticoids markedly potentiate this effect. As pro-TRH is expressed in a subpopulation of somatotrophs, our data suggest that the TRH gene in this location may be coordinately regulated with the GH gene.

Processing of proTRH to its intermediate products occurs before the packing into secretory granules of transfected AtT20 cells.

The intracellular compartments where posttranslational processing of proTRH takes place have not been identified. Using AtT20 cells transfected with a complementary DNA for preproTRH, we have used purified antibodies that recognize the intact precursor, intermediate and end products of processing to identify the subcellular compartments in which cleavage occur. Further, pulse-chase experiments followed by subcellular fractionation were undertaken to determine the order of processing of proTRH during its transport to the secretory granules. Cells were homogenized by nitrogen cavitation and subjected to a centrifugation of 1.065 mg/ml density gradient of Percoll to separate secretory granules (SG) from rough endoplasmic reticulum (RER)/Golgi apparatus. The purity of the SG and RER fractions was assessed by assays of marker enzymes for mitochondria, RER, Golgi, and cytoplasm. ProTRH derived cryptic peptides and TRH in each fraction were determined by RIA. Golgi and SG fractions were subjected to polyacrylamide gel electrophoresis followed by extraction and RIA. Using the anti-pCC10 antiserum which recognizes intact (26 kd) as well as partially processed prohormone, the RER/Golgi fraction contained 0.3 pmol intact ProTRH and 0.2 pmol each 15 and 6 kilodalton (kDa) fragments; the SG contained the 15 kDa moiety (0.2 pmol) along with a 6 kDa (0.4 pmol) material but not the 26 kDa ProTRH. The SG were also enriched by 0.21 pmol pYE27 (PreproTRH 25-50), 0.23 pmol pFT (PreproTRH 53-74), 0.31 pmol pEH24 (PreProTRH 86-106), and 0.5 pmol TRH. None of these were present in the RER/Golgi. Pulse-chase studies also showed that the intact proTRH (26 kDa) precursor was only present in the RER/Gg fraction along with two of its N-terminal intermediate processing products, a 15 k mol wt peptide and a 6 k mol wt peptide, and two of its C-terminal processing products, a 16.5 k mol wt and a 9.6 k mol wt peptides. In addition, fully processed peptides as well as TRH were only detected in the neurosecretory granules. These observations suggest that after the initial conversion of proTRH in the RER/Golgi fraction, the peptides are delivered to the granules where processing to TRH and cryptic peptides takes place. Supporting this, our pulse-chase studies unequivocally showed that, pEH24, an end product of proTRH processing, was only produced in secretory granules. Thus, initial cleavage of the TRH precursor may be required for packing and sorting of the end products to occur.

Identification of the thyrotropin-releasing hormone-prohormone and its posttranslational processing in a transfected AtT20 tumoral cell line.

By using an AtT20 cell line transfected with complementary DNA for preproTRH, we have identified the proTRH polyeptide precursor [26 kilodaltons (kDa)] and shown that this molecule gives rise to the proTRH derived sequences as determined by pulse-chase and trypsinization studies. The predicted proTRH precursor composed of 231 amino acids with 5 copies of a TRH progenitor sequence (Gln-His-Pro-Gly) and 7 other cryptic peptides was demonstrated by: 1) Western Blot analysis of an AtT20 cell extract with anti-pCC10 antibodies (an antibody that recognizes the intact prohormone as well as some intermediate products of processing); 2) Immunoprecipitation of the radiolabelled 26 kDa protein with anti-pCC10 followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis; 3) Gel filtration chromatography of the radiolabeled 26 kDa extracted from SDS-PAGE. 4) RIA with anti-pCC10 antiserum against peptides extracted from adult rat hypothalamus and olfactory lobe after SDS-PAGE. 5) Trypsinization of the proTRH precursor which generated the proTRH cryptic peptides preproTRH25-50 (pYE27) and preproTRH53-74 (pFT22). These moieties were also produced during trypsinization of intermediate products of processing. By means of pulse-chase studies, the 26 kDa polypeptide was shown to be the biosynthetic precursor to all the proTRH derived cryptic peptides. Cleavage at two positions in the center of the molecule (Lys107-Arg108 and Lys152-Arg153) generated two moieties of 16.5 and 15 kDa. The 15 kDa N-terminal fragment is later cleaved to a 6 kDa peptide that includes the proTRH derived peptides, pYE27, pFT22, and pEH24. The carboxy-terminal 16.5 kDa fragment of the prohormone is processed to a 9.6 kDa fragment which contains the proTRH derived peptide pST10 (preproTRH160-169) and a fragment of 5.4 kDa that may be the C-terminal peptide preproTRH208-255 recognized by antisera pAC12 and pYE17. In further processing, the 9.6 kDa molecule is cleaved to produce a 5.4 kDa peptide from either sequences 115-169 or 160-199.

Partial purification and characterization of a novel growth hormone-releasing factor (GRF) from teleost brain related to the rat hypothalamic peptide.

A growth hormone-releasing factor (GRF)-like molecule has been partially purified and characterized from acid extracts of codfish (Gadhus morhua) brain using immunoaffinity and gel chromatography, followed by HPLC. This material has a mol.wt. which is similar to known mammalian forms of GRF but is immunologically and/or chromatographically distinct from previously described GRF peptides. However, it is related to rat(r) GRF(1-43) since it causes marked displacement in the rGRF RIA. Codfish GRF is a highly specific and potent hypophysiotropic factor as shown by its ability to stimulate the release of GH, but no other hormone, from rat anterior pituitary cells in vitro. These findings suggest that, phylogenetically, GRF is an ancient molecule with its biologic activity and certain immunoreactive domain(s) conserved, at least, from teleost to mammal.

Controversies in TRH biosynthesis and strategies towards the identification of a TRH precursor.

It is now clear that TRH is derived from posttranslational processing of a precursor polyprotein like other hypothalamic releasing factors and not by a soluble nonribosomal enzymatic mechanism. With an oligonucleotide probe directed against a presumptive TRH progenitor sequence, a frog skin cDNA library was screened and a clone identified coding for a peptide of 123 amino acids containing four copies of the TRH progenitor sequence (Gln-His-Pro-Gly) flanked by paired basic amino acid residues. The amphibian probe did not, however, hybridize with mammalian hypothalamus. To identify the TRH precursor in the rat hypothalamus, an antiserum was raised against the synthetic decapeptide sequence, Cys-Lys-Arg-Gln-His-Pro-Gly-Lys-Arg-Cys. It was hypothesized that the N- and C-terminal cysteines would cyclize, permitting an antibody to be generated against the midregion of the molecule and its extended counterpart sequences in nature pro-TRH. Such an antiserum was generated that recognized the intact or partially processed precursor immunohistochemically and was used to identify the prepro-TRH cDNA on screening of a rat hypothalamic lambda gt11 expression library. The rat precursor is similar to the amphibian only insofar as multiple copies of the TRH sequence are encoded in each. Thus, the resolution of the contentious question of the mode of TRH biosynthesis in the rat hypothalamus required the development of a novel antiserum, screening by immunocytochemistry and the application of modern molecular biological techniques.

Molecular forms of gonadotropin-releasing hormone associated peptide (GAP): changes within the rat hypothalamus and release from hypothalamic cells in vitro.

We have developed RIAs using antisera directed against the cryptic peptide of the GnRH precursor (termed GnRH-associated peptide, GAP) and have used these together with a GnRH assay to characterize proGnRH-derived peptides in rat hypothalamic extracts. On Sephadex chromatography we have identified three molecular forms of GAP-like immunoreactivity (GAP-LI), in addition to the GnRH decapeptide. The largest of these forms is an 8.0-kilodalton (kD) GAP-LI which appears to be the complete proGnRH peptide. The second is a 6.5-kD GAP-LI, and is similar to the complete cryptic peptide (i.e. proGnRH14-69 or GAP1.56). The third peptide is a 2.5 kD C-terminal fragment of the cryptic peptide, representing a processed form of GAP. In whole hypothalamic extracts from normal rats the 8.0-kD form was the major form, comprising 60-70% of the total GAP-LI. All three forms were present in three distinct areas of the rat hypothalamus, namely median eminence (ME), anterior and mid-hypothalamus. However in the ME the proportion of 8.0-kD GAP-LI was significantly reduced and the proportion of 6.5-kD GAP-LI significantly increased compared to anterior and mid-hypothalamic samples (p less than 0.05). In whole hypothalamic extracts from pregnant and lactating rats the total content of proGnRH-derived peptides was reduced but the relative proportions of these peptides were not significantly changed from normal female rats. However, in postlactating rats, 2 weeks after removal of pups, the total levels of GAP-LI were unchanged compared to normals, but the percentage of 8.0-kD GAP-LI was significantly decreased and the percentage of 2.5-kD GAP-LI significantly increased compared to normals (p less than 0.05), suggesting that proGnRH may undergo additional processing dependent on physiological condition. In fetal and neonatal rats the proportion of the 6.5-kD peptide was increased and that of the 8.0-kD peptide decreased compared to adults, and this change became less significant with increasing age. In ovariectomized rats the proportion of 6.5-kD GAP-LI was increased and that of 8.0-kD GAP-LI decreased; this change was partially reversed with steroid treatment. Both the 6.5 and 2.5-kD forms were released by high K+ stimulation of neonatal hypothalamic cells in culture. These results indicate that there is differential processing of the proGnRH precursor within the hypothalamus and in altered physiological states.

Identification, characterization and localization of thyrotropin-releasing hormone precursor peptides in perinatal rat pancreas.

The sequence of rat hypothalamic prepro TRH, deduced from its complementary DNA, contains five TRH progenitor sequences and six cryptic sequences separated by paired basic amino acid residues. We have utilised antisera against two synthetic peptides corresponding to sequences within proTRH, [Tyr53] preproTRH (53-74), part of the amino terminal leader sequence of proTRH and [Cys 74,83] preproTRH-(75-82), representing a TRH progenitor sequence flanked by cysteine residues (pCC10) in radioimmunoassays (RIA) to identify and chromatographically characterize proTRH derived peptides in extracts of rat perinatal pancreas and to localize these peptides immunohistochemically. Two forms of immunoreactive pYT22 (ipYT22) were observed, similar in size to ipYT22 seen in extracts of adult rat brain. By RIA immunoreactive pCC10 was detectable in neonatal but not fetal pancreas. However, immunohistochemical double staining of both fetal and neonatal rat pancreas colocalized both ipYT22 and ipCC10 with immunoreactive insulin in the B-cell of the developing Islets of Langerhans. These findings indicate that the B-cell of the perinatal pancreas synthesizes TRH from a prohormone encoded by a mRNA similar to that present in adult rat hypothalamus.

Post-translational processing of thyrotropin-releasing hormone precursor in rat brain: identification of 3 novel peptides derived from proTRH.

The sequence of rat hypothalamic pro-thyrotropin releasing hormone, deduced by sequencing of cDNA, in addition to 5 TRH progenitor sequences contains leader, trailer and 4 intervening sequences separated by paired basic amino acid sequences. We have developed radioimmunoassays to synthetic peptides corresponding to portions of these cryptic proTRH sequences and have used these assays to identify and partially characterize proTRH peptides, distinct from TRH, in extracts of rat brain. Two of these peptides correspond closely in size to one intervening sequence and the carboxy-terminal sequence of proTRH. Three other peptides correspond to the intact amino-terminal leader sequence and two peptides formed by a further cleavage of the leader sequence at an internal paired basic amino acid sequence.

Biosynthesis of thyrotropin-releasing hormone by a rat medullary thyroid carcinoma cell line.

Prepro-thyrotropin-releasing hormone (TRH) messenger RNA was detected in the rat medullary thyroid carcinoma cell line CA77. The RNA of 1.6 kilobases comigrated with that found in rat hypothalamus. Using three radioimmunoassays specific for pro-TRH-derived peptides, we demonstrated that CA77 cells synthesize high levels of immunoreactive TRH and all of the other pro-TRH-derived peptides identified in hypothalamic tissue. The relative levels of the pro-TRH-derived peptides also indicate that CA77 cells process the TRH precursor in a manner similar to hypothalamic tissue. CA77 cells provide a promising model system for further studies of prepro-TRH gene regulation and post-translational maturation.

GRF immunoreactive neurons in the paraventricular nucleus of the rat: an immunohistochemical study with monoclonal and polyclonal antibodies.

Our study demonstrates a complex GRF neuronal system within the rat hypothalamus. Using both high affinity polyclonal and high specificity monoclonal antibodies to rat (r) GRF, we have substantiated evidence for immunoreactive GRF (GRF-i) perikarya in the parvocellular portion of the paraventricular nucleus. Other hypothalamic areas containing rGRF-positive perikarya include the lateral arcuate nucleus, lateral hypothalamus, perifornical area and dorsomedial nucleus. GRF-i neuronal terminals were seen in the external zone of the median eminence, more rostrally in the periventricular nucleus, and near the suprachiasmatic nucleus and more caudally in the dorsomedial nucleus and ventral premammillary nucleus.