Journal of Histochemistry and Cytochemistry, Vol. 45, 1623-1628, Copyright © 1997 by The Histochemical Society, Inc.


ARTICLE

Thyrotropin-releasing Hormone Immunoreactivity in Rat Adrenal Tissue Is Localized in Mast Cells

Jean-Jacques Montagnea, Ali Ladrama, Dominique Grouselleb, Pierre Nicolasa, and Marc Bulanta
a Laboratoire de Bioactivation des Peptides, Institut Jacques Monod, Paris, France
b Unité de Dynamique des Systèmes Neuroendocriniens, INSERM U 159, Paris, France

Correspondence to: Marc Bulant, Laboratoire de Bioactivation des Peptides, Institut Jacques Monod, 2 place Jussieu, 75251 Paris Cedex 05, France.


  Summary
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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. (J Histochem Cytochem 45:1623-1627, 1997)

Key Words: neuropeptide, mast cells, immunocytochemistry, HPLC


  Introduction
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Thyrotropin-releasing hormone (TRH), originally isolated from hypothalamus, is a potent stimulator of thyroid-stimulating hormone (TSH) release after binding to its high-affinity receptor on the thyrotrope cells. TRH has since been identified throughout the central nervous system, including the retina and the spinal cord (Morley 1981 ). Pharmacological studies in animals have led to the consideration that TRH may function as a neurotransmitter, in addition to having hypophysiotropic effects (Jackson 1982 ). This tripeptide is synthesized as a large precursor protein containing multiple copies of the progenitor sequence Gln-His-Pro-Gly, each bracketed by typical dibasic cleavage sites and linked together by connecting fragments (Lechan et al. 1986 ). Proteolytic processing of the rat precursor is expected to produce five copies of TRH along with several connecting peptides and various C- and/or N-terminally extended forms of TRH. A variety of data have provided evidence for the coexistence of partial and complete processing of pro-TRH in various regions of the rat brain (Cockle and Smyth 1987 ; Wu et al. 1987 ; Bulant et al. 1988 ). Like other neural peptides, TRH occurs outside the CNS in neuroendocrine cells. It is present in ß-cells of pancreatic islets (Leduque et al. 1987 ), in parafollicular cells of the thyroid gland (Gkonos et al. 1989 ), and in Leydig cells of the testis (Feng et al. 1993 ; Montagne et al. 1996 ). Although TRH in pharmacological concentrations has been demonstrated to exert multiple effects on tissues other than the pituitary, the physiological significance of the peripheral TRH and the respective contribution of each tissue from which it comes have not been clearly established. In that regard, TRH has been identified in extracts of rat adrenal glands (Simard et al. 1989 ; Fuse et al. 1990 ), but the cellular localization of TRH immunoreactivity and whether adrenal and neural pro-TRHs are identical remain unknown. In the present study we investigated the presence of both TRH and a prepro-TRH connecting peptide, the prepro-TRH[160-169] (Ps4), in rat adrenal glands by combining molecular sieve filtration and HPLC with EIA detection. Using immunocytochemistry, we also examined the localization of TRH in rat adrenal gland at the cellular level.


  Materials and Methods
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Materials and Methods
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Enzyme Immunoassay (EIA) Procedures
TRH EIA was performed as previously described (Montagne et al. 1996 ). Ps4 was measured by EIA using an enzymatic tracer kindly provided by Drs. C. Creminon and P. Pradelles (CEA; Saclay France). Briefly, the enzymatic tracer was obtained by covalent coupling of the N-terminal amine of Ps4 with the pure tetrameric G4 form of acetyl cholinesterase. Second antibody solid-phase EIA of Ps4 was performed in 96-well microtiter plates coated with mouse monoclonal anti-rabbit immunoglobulins to ensure separation between bound and free moieties of the tracer. The assay was carried out in a volume of 150 µl assay buffer (0.1 M potassium phosphate, pH 7.4, containing 0.4 M NaCl, 1 mM EDTA, and 0.1% BSA). A mixture of 50 µl diluted enzymatic tracer (1:200), 50 µl diluted anti-Ps4 antiserum (lot 371-1406; 1:40,000) and 50 µl standard or biological extract was incubated for 18 hr at 4C. After washing, the enzymatic activity in each well was measured using Ellman's method. The Ps4 EIA system, using Ps4 as standard and Ps4 coupled to acetylcholinesterase as an enzymatic tracer, recognized authentic Ps4 (detection limit 80%; B/Bo = 6 fmol).

Chromatographic Separation
Sixteen adult male Sprague-Dawley rats (Dépré; Saint Doulchard, France) weighing 300 g were sacrificed by decapitation and their whole adrenal glands were immediately removed. Tissues were immersed in 10% acetic acid at 95C for 10 min and then homogenized and extracted at 4C using a polytron homogeneizer. The resulting suspension was centrifuged at 3000 x g at 4C for 30 min and lyophilized. Crude adrenal extracts were first filtered through a Sephadex G-50 (fine) column at a flow rate of 8 ml/hr. For HPLC studies, the prepurified sample was dissolved in 200 µl of water plus 0.1% trifluoroacetic acid (TFA) and applied to 5-µm Lichrospher C-18 reverse-phase column (3.9 x 250 mm; Interchrom, Asnières, France) equilibrated with the same solvent at a flow rate of 0.75 ml/min. Three min after injection the bound material was eluted with a linear gradient (1%/3 min) of acetonitrile (0.07% TFA) in 0.1% TFA/water. Fractions of 750 µl were collected and lyophilized. Aliquots of each fraction were reconstituted in EIA buffer and assayed for TRH or Ps4 immunoreactivity.

Histology and Immunocytochemical Procedure
Two rats were perfused intracardiacally with heparinized saline (100 ml) and then with an infusion of 200 ml of McLean's fixative containing 2.5 mM sodium m-periodate, 18.7 mM L-lysine monohydrochloride, 0.1 M phosphate buffer (PB), pH 7.4, and 4% paraformaldehyde. The adrenal glands were removed and postfixed for 4 hr at 4C in the same fixative, washed in successive sucrose baths (5%, 15%, and 25%), embedded in Tissue Tek, frozen in liquid nitrogen, and cut on a cryostat at 8 µm. Sections were mounted on chromalum/gelatin-coated slides, air-dried, and then processed according to the indirect immunofluorescence method. Sections were rinsed in PB and incubated in 5% normal goat serum in 0.3% Triton X-100/PB for 1 hr at 25C. Visualization of the location for immobilized antigen was made using an incubation step with anti-TRH immunoglobulins (Igs F18, 1:400, 47 µg/ml, 12 hr at 4C) and a second incubation with a goat anti-rabbit immunoglobulin-fluorescein isothiocyanate (Sigma; St Louis, MO) (1:160, 1 hr at 25C) in PB containing 1% normal goat serum and 0.3% Triton X-100. The immunoglobulins F18 were purified from rabbit anti-TRH antiserum (4B18) by precipitation with 18% Na2SO4. For control, anti-TRH Igs were preabsorbed with TRH fixed on Sepharose beads as previously described (Faivre-Bauman et al. 1980 ) and replaced the primary immunoglobulins (1:400, 18 µg/ml, 12 hr at 4C). Sections to be stained with Toluidine Blue were rinsed with 0.5 M HCl for 5 min, stained with 0.5% (w/v) Toluidine Blue in 0.5 M HCl for 30 min, and washed with 0.5 M HCl for 30 sec (Xu et al. 1993 ). In the Acian blue method, sections were stained with 0.5% (w/v) Alcian blue in 0.7 M HCl for 10 min and counterstained with 0.25 (w/v) Safranin O.


  Results
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Materials and Methods
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To detect the presence of peptides derived from pro-TRH in rat adrenal glands, tissue extract was subjected to size fractionation using Sephadex G-50 and reverse-phase HPLC analysis. Fractions were analyzed by EIA with two antisera directed against pro-TRH-derived products. By use of a TRH antiserum, a sharp immunoreactive peak was detected that emerged from the total volume of the column (Figure 1A). Application of the Ps4 EIA in the same procedure demonstrated the presence of immunoreactive material (Figure 1B). The predominant product co-eluted with synthetic Ps4 during gel filtration. To characterize more precisely the major pro-TRH-related products from adrenal glands, immunoreactive fractions 57-60 corresponding to the most immunoreactive fractions for either TRH or Ps4 EIA during gel filtration were pooled and subjected to reverse-phase HPLC on a 5-µm Lichrospher OD2 column with a very slow gradient of acetonitrile in water plus 0.1% TFA (Figure 1C). Under these conditions, the putative endogenous TRH from G-50 was fractionated into a major immunoreactive peak corresponding to TRH, which was accompanied by a minor trailing shoulder and two additional species. Aliquots of the fractions depicted in Figure 1C were also assayed for Ps4 immunoreactivity. Authentic Ps4 was recovered as a predominant immunoreactive species eluting in the same position as synthetic Ps4. Two additional and uncharacterized immunoreactive peaks were also detected in significant amounts.



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Figure 1. Fractionation by molecular sieve filtration and reverse-phase HPLC of TRH- and Ps4-immunoreactive peptides extracted from rat adrenal glands. (A,B) Extracts were fractionated on a Sephadex G-50 (fine) column (68 x 1.6 cm) in 10% acetic acid. Elution of TRH (A) and Ps4 (B) immunoreactivity was monitored by enzyme immunoassay on an aliquot of each of the 2-ml fractions. (C) Fractions 57-60 from the Sephadex G-50 column were recovered and injected onto a Lichrospher OD2 HPLC column. An aliquot of each 1-63 fraction was tested for its TRH immunoreactivity. An aliquot of each remaining fraction (64-123) was tested for its Ps4 immunoreactivity. The column was postcalibrated with synthetic TRH and Ps4, whose respective positions are indicated by the arrows.

Immunocytochemical localization of adrenal TRH-related peptides was examined in rats using specific anti-TRH immunoglobulins. Observation of the sections indicated that both the adrenal cortex and medulla were devoid of TRH immunoreactivity. At the light microscopic level, specific labeling was observed in scattered cells located in the brown adipose tissue (BAT) surrounding the adrenal glands (Figure 2A). These cells contained a distinguishable nucleus and were observed everywhere in BAT (Figure 2B), although most of them were proximal to the adrenal capsule. These cells were positively stained when sections were treated with Toluidine Blue (pH <2.5), which identifies mast cells. To determine if TRH-immunoreactive cells accounted for all of the adrenal mast cells, we first counted all of the fluorescent cells, then counterstained the sections with acidic Toluidine Blue. No additional metachromatic cells were evident within the tissue sections (Figure 2C-E). With an Alcian blue/Safranin mixture, mast cells stained red, indicating that they correspond to typical connective tissue mast cells (data not shown). No fluorescence was observed with TRH-treated anti-TRH immunoglobulins (Figure 2F).



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Figure 2. Immunocytochemical study demonstrating the presence of TRH immunoreactivity in mast cells. The mean (± SEM) number of mast cells in 8-µm transverse sections was 16.5 (± 2.6). (A) Part of a transverse section of rat adrenal gland treated for TRH detection. Fluorescent cells are scattered around the adrenal gland. (B) At higher magnification, immunostaining was confined to cells surrounded by adipocytes (C-E). Cross-identification of cells showing TRH immunoreactivity by overstaining of the section with acidified Toluidine Blue (E and D inset). (F) Depletion of TRH immunoglobulins in primary immunoglobulins prevented staining. Arrowhead indicates a post-identified mast cell. Ca, Capsule; ZG, zona glomerulosa; ZF, zona fasciculata; CV, capsular vessel. Bars = 20 µm.


  Discussion
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Several studies have indicated the presence of TRH in rat adrenal gland (Simard et al. 1989 ; Fuse et al. 1990 ), but its cellular localization and physiological significance were unknown. The present study demonstrates that adrenal TRH derives from a precursor molecule similar or closely related to hypothalamic pro-TRH. Despite the low level of TRH and Ps4 immunoreactivity (<10 fmoles/adrenal glands), we have identified from 32 glands two forms that correspond to authentic TRH and Ps4. Connecting peptide Ps4 is a non-TRH peptide, which is yielded from the complete processing of the prohormone in the CNS. Several additional peaks of material immunoreactive in the homologous TRH and Ps4 EIA were also detected during chromatographic analysis of the adrenal gland extracts. These peaks were not further characterized because of the small amount available, but they may be derived from processing of pro-TRH in rat adrenal glands. Conversely, these immunoreactive peaks could comprise either proteolytic degradation products of pro-TRH or unidentified substances crossreacting in the assays. Taken together, these data indicate that Ps4 and TRH appear to be major endproducts. The cellular localization of TRH-immunoreactive peptides was obtained through immunocytochemical study using anti-TRH immunoglobulins. Intensive labeling was observed in scattered cells around the adrenal gland capsule, in BAT. These cells can be characterized as tissue basophils with Toluidine Blue and Alcian Blue. On the basis of the size and aspect of their nuclei, these basophils are typical mast cells, as previously described in the BAT (Mory et al. 1983 ). These data indicate that TRH-immunoreactive peptides are unequivocally localized in rat mast cells surrounding the adrenal glands. Moreover, the fact that absolutely no staining was seen anywhere else in the sections strongly suggests that authentic TRH, which is detected during HPLC separation as a major product, plays a great part in this signal. Preliminary PCR experiments in adrenal glands have permitted amplification of a 600-BP internal fragment of the pro-TRH mRNA (data not shown). Taken together, our observations are strong evidence that TRH identified in rat adrenal gland extracts is synthesized in mast cells from a precursor similar to that found in rat hypothalamus.

The level of TRH expressed in the mast cells is probably too low to exert endocrine hormonal effects on distant tissues, but it appears adequate to support local paracrine or autocrine regulatory effects. Interestingly, it has been reported that TRH receptor mRNA is widely distributed in rat peripheral tissues and that a substantial amount of mRNA was observed in adrenal glands (Fukusumi et al. 1995 ). Identification of the cell type that expresses TRH receptor should enable identification of the role of local TRH.


  Acknowledgments

We are grateful to Dr G. Mory for his pertinent comments.

Received for publication March 31, 1997; accepted June 25, 1997.


  Literature Cited
Top
Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

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