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The Thyrotropin (Thyroid-Stimulating Hormone) Receptor Is Expressed on Murine Dendritic Cells and on a Subset of CD45RB^high Lymph Node T Cells: Functional Role for Thyroid-Stimulating Hormone During Immune Activation¹

E. Ümit Bariaçik and John R. Klein²

Department of Biological Science and the Mervin Bovaird Center for Studies in Molecular Biology and Biotechnology, University of Tulsa, Tulsa, OK 74104

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
Thyroid-stimulating hormone (TSH), a central neuroendocrine mediator of the hypothalamus-pituitary-thyroid axis, has been shown to affect various aspects of immunological development and function. To gain a better understanding of TSH involvement within the mammalian immune system, the expression and distribution of the TSH receptor (TSHr) has been studied by immunoprecipitation and by flow cytometric analyses. Using highly enriched populations of B cells, T cells, and dendritic cells, trace amounts of TSHr were precipitated from B cells and T cells, whereas high levels of TSHr were precipitated from the dendritic cell fraction. Flow cytometric analyses of TSHr expression on splenic and lymph node T cells revealed a major difference between those tissues in that only 2–3% of splenic T cells were TSHr⁺, whereas 10–20% of CD4⁺8^- and CD4^-8⁺ lymph node T cells expressed the TSHr, which was exclusively associated with CD45RB^high cells and was not expressed during or after activation. The TSHr was not present on cells of the immune system during fetal or neonatal life. However, recombinant TSHß was found to significantly enhance the phagocytic activity of dendritic cells from adult animals and to selectively augment IL-1ß and IL-12 cytokine responses of dendritic cells following phagocytic activation. These findings identify a novel immune-endocrine bridge associated with professional APCs and naive T cells.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
The notion that the immune system and the neuroendocrine system are physiologically and functionally linked has been realized for some time and has been empirically demonstrated in a number of studies. To the present, however, most of those have examined the relationship between immune function and hormones of the hypothalamus-pituitary-adrenal axis; in particular, the involvement of the glucocorticoids and other "stress" hormones (1). Those biological mediators and their derivatives generally exert suppressive effects on the host’s immune response to Ag, and thus have been used clinically to curtail the severity of autoimmune reactions and allograft rejection responses (2, 3, 4).

The hypothalamus-pituitary-thyroid (HPT)³ axis is a neuroendocrine pathway used in development and throughout metabolic regulation. This involves an orchestrated process of hormone release and feedback involving the hypothalamic-derived neuropeptide, thyrotropin-releasing hormone (TRH); the anterior pituitary-derived hormone, thyroid-stimulating hormone (TSH); and the thyroid-derived hormones (tri-iodothyroxine (T₃) and thyroxine (T₄)). With the exception of the direct involvement of HPT hormones in thyroid autoimmunity (reviewed in ref. 5) and thyroid-immune system interactions by hormones and cytokines (6, 7, 8, 9), knowledge about the involvement of HPT hormones on immunity remains scant. Yet, evidence exists indicating that TRH and TSH can directly or indirectly influence peripheral immunity in a number of ways. For example, TRH has been reported to have costimulatory effects on mitogen-induced lymphocyte responses of rat spleen cells (10), and TSH has been shown to augment Ag-specific spleen plaque-forming cell responses in mice (11, 12, 13). Those apparent effects may be indirect, however, as inferred from studies demonstrating TSH binding to monocytic cells (14). Other studies have demonstrated that HPT hormones, mediated primarily by TSH, can alter the immunological composition of lymphoid cells dispersed throughout the intestinal epithelium (15, 16, 17). This occurs via a local network of TSH hormone synthesis and utilization in which TSH is produced by intestinal enterocytes and is utilized by intestinal lymphoid cells (18).

Still to be learned about the systems described above is the nature of hormone communication within the immune system, i.e., the specific cells that are involved, the molecular signals used and how they affect the overall immunobiological process, and whether additional intermediate mediators are involved in the delivery of hormone signals to target cells and tissues. In the present study, we have examined the expression of the TSH receptor (TSHr) on cells of the thymus, spleen, and lymph nodes to better understand the cells of the immune system involved in TSH utilization and to provide information about the pathways of TSH-mediated hormone communication within primary and secondary lymphoid tissues. Our findings indicate that the TSHr is expressed in a remarkably selective manner throughout cells of the peripheral immune system. The implications of this in the context of neuroendocrine homeostatic regulation of immunity are discussed.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Mice and reagents

C57BL/6, BALB/c, and CB6F₁ mice used in the study were purchased from The Jackson Laboratory (Bar Harbor, ME). Data reported are from C57BL/6 mice; similar findings were obtained with BALB/c and CB6F₁ mice. C.RF-Tshr^hyt/hyt hypothyroid mice were raised at the University of Tulsa from breeding pairs obtained from The Jackson Laboratory. Mice homozygous for the TSHr mutation were identified by PCR analyses and DNA sequencing across the mutation region. The medullary thyroid carcinoma mouse (MTC-M) cell line (1806-CRL) was obtained from the American Type Culture Collection (Manassas, VA). Recombinant human TSH was obtained from Sigma (catalogue no. T-4533; St. Louis, MO).

Abs and flow cytometry

Abs used in this study were FITC-labeled anti-CD8 (CT-CD8s; Caltag, South San Francisco, CA), FITC- and PE-labeled anti-CD5 (53-7.3), FITC-labeled anti-CD45RB (23G2), PE-labeled anti-CD4 (RM4-5), PE- and FITC-labeled anti-MHC-II (39-10-8), PE-labeled anti-CD69 (H1.2F3), biotin-labeled anti-CD19 (ID3), PE-labeled anti-CD11c (HL3), biotin-labeled and unlabeled anti-CD11b (MI/70), biotin-labeled and unlabeled anti-MHC-II (39-10-8), biotin-labeled anti-TCRß (H57-597), FITC- and PE-labeled isotype/species- matched Abs for control staining, anti-CD16/32 for Fc receptor blocking before staining, and PE-streptavidin ( all reagents; PharMingen, San Diego, CA). Unlabeled anti-Thy-1.2 (J1j.10), anti-CD24 (J11d.2), anti-CD4 (GK1.5), anti-CD8 (3.155), and anti-Mac1 (MI/70) (American Type Culture Collection) were used for complement-mediated lysis. Blocking with unlabeled TSH was done by culturing 2 x 10⁵ freshly isolated splenic dendritic cells in 100 µl of supplemented medium with 100 µl of 10^-4, 10^-5, or 10^-6 M TSH for 25 min at 4°C. Cells were washed and reacted with biotin-labeled recombinant TSH for 25 min at 4°C and analyzed by flow cytometry.

Recombinant human TSH was biotinylated using N-hydroxysuccinimidobiotin (Sigma H1759). Thirty-five micrograms of NHS-biotin was added to 0.1 mg of recombinant TSH in 300 µl of 0.1 M carbonate buffer (pH 9.0) and incubated for 3 h at room temperature. Four microliters of 1 M NH₄Cl was added and incubated for 15 min at room temperature. The reaction was washed twice with PBS in a Micron-10 microconcentrator (Amicon, Beverly, MA) and resuspended in 300 µl of PBS for use.

Flow cytometric analyses was done using an Epics 751 flow cytometer (Coulter, Hialeah, FL) interfaced to a Cicero data acquisition system (Cytomation, Fort Collins, CO). All experiments included cells stained with appropriate isotype/species-matched control Abs from which the positions of the cursors were determined as shown in the histograms.

Cell isolations, enrichment, and in vitro culture

Lymphoid cells from the small intestine were isolated as described previously (19). Single cell suspensions of spleen cells, thymocytes, and lymph node cells were prepared by pressing tissues through a 60-mesh stainless steel screen. Enrichment of splenic T cells and B cells was done using published techniques with minor modifications. For T cell enrichment (20), spleen cells were incubated with anti-Mac-1, anti-CD24, and anti-MHC-II mAbs at 4°C for 30 min, washed, and reacted for 15 min at 37°C with 10% Low-Tox guinea pig complement (Accurate Chemicals, Westbury, NY). The complement treatment was repeated and treated cells were passed through a nylon wool column for depletion of B cells and adherent cells.

For B cell purification (21), spleen cells were collected and incubated at 1 x 10⁸ cells/10 ml in 100- mm tissue culture plates (Fisher Scientific, Dallas, TX) at 37°C in 5% CO₂ for 1 h. Nonadherent cells were recovered and erythrocytes were lysed with 0.83% ammonium chloride. Cells were washed, layered onto a discontinuous gradient of 50, 60, 70, and 80% Percoll (Pharmacia, Uppsala, Sweden), and centrifuged for 20 min at 600 x g. B cells were collected from the 60 to 70% Percoll interface and residual T cells were removed by treatment with anti-Thy-1.2, anti-CD4, anti-CD8, and anti-Mac1 Abs plus complement. Cells were centrifuged through a 50–80% Percoll gradient and cells were recovered from the 60 to 70% interface to obtain the viable B cell-enriched population.

Dendritic cell enrichment was done according to the method of Ridge et al. (22) with modifications. Briefly, spleens were isolated from 6 to 10 mice and single-cell suspensions were prepared in RPMI 1640 containing 10% FBS. Cells were incubated at a concentration of 5 x 10⁷cells/10 ml for 1.5 h at 37°C in tissue culture-treated petri dishes (Fisher Scientific). Plates were gently washed three to five times with warm medium followed by PBS to remove nonadherent cells. Adherent cells were then incubated at 37°C overnight in 5 ml of medium containing 5 ng/ml GM-CSF, collected by rinsing with medium and PBS, and depleted of residual T cells and B cells by complement-mediated lysis using anti-CD3 and anti-B220 mAbs. Viable cells were collected by centrifugation over 50% Percoll. Dendritic cells and lymphocytes were recovered from day 18 fetal mice and day 7 neonatal mice. Age of fetal mice was determined by checking each morning for vaginal plugs in breeding-paired mice; plugged animals were defined as fetal day 1.

For in vitro stimulation of T cells, 60-mm petri dishes were coated with anti-CD3 Ab overnight at 4°C. Media were removed from plates and 5 ml of 3 x 10⁶ cells/ml was cultured in RPMI 1640 supplemented with FBS (10% v/v), 100 U/ml penicillin-streptomycin, 2 mM L-glutamine, and 5 x 10^-5 M 2-ME (all reagents; Sigma). After 48 h, cells were collected and centrifuged over Ficoll-Paque (Sigma) at 400 x g for 20 min. Viable cells from the liquid interface were collected, washed, and stained for flow cytometry.

Immunoprecipitation and Western blotting

A total of 10 x 10⁶ freshly isolated thymocytes, whole spleen cells, fractionated spleen cells, or 3–5 x 10⁶ MTC-M cells was lysed in detergent buffer consisting of 50 mM Tris-HCl (pH 7.4), 150 mM NaCl, 1 mM EGTA, 1 mM NaF, 1 mM PMSF, 1 µg/ml aprotinin, leupeptin, and pepstatin, 1% Nonidet P-40, and 0.25% deoxycholate (all reagents; Sigma). Precleared lysates were mixed overnight with 10 µl of monoclonal anti-TSHr Ab (clone 28) (23) (ABR, Golden, CO) at 4°C, followed by 40 µl of protein A-agarose (Sigma) for 2 h. Precipitates were collected by centrifugation, washed, boiled in 2x reducing SDS sample buffer, and electrophoresed through a 10% polyacrylamide gel (Bio-Rad, Hercules, CA). Proteins were transferred electrophoretically to Immuno-Blot polyvinylidene difluoride membranes (Bio-Rad), blocked with 3% nonfat dry milk in PBS, reacted with anti-TSHr mAb (clone 49) (23) (ABR) overnight at 4°C, followed by the addition of biotinylated anti-mouse Ig (PharMingen) for 2 h, and streptavidin-HRP (Amersham, Buckinhamshire, U.K.) for 30 min. Enhanced chemiluminescence (Amersham) was used for autoradiographic identification of proteins.

cAMP and cytokine assays

A total of 5 x 10⁵ freshly isolated splenic dendritic cells from normal mice and C.RFTshr^hyt/hyt mice were cultured in 1 ml of unsupplemented DMEM with 1) medium alone, 2) 10^-7-10^-9 M recombinant TSH, or 3) 10^-7 M forskolin (Sigma) in the presence of 1 mM 3-isobutyl-1-methylxanthine (Sigma), a phosphodiesterase inhibitor. After 15 min, cells were collected, pelleted by microfuge centrifugation, lysed in 0.1 M HCl, and cAMP activity was assayed using a competitive ELISA assay (R&D Systems, Minneapolis, MN) according to the manufacturer’s protocol. Determination of cytokine activity was made using commercial cytokine assay kits according to the manufacturer’s protocols (IL-1ß, IL-6, and TNF-, R&D Systems; IL-12, Genzyme, Cambridge, MA).

Activation of dendritic cells by phagocytosis

Phagocytosis by dendritic cells was done using methods similar to those reported by others (24). A total of 5 x 10⁵ freshly isolated splenic dendritic cells was cultured for 3 or 9 h in supplemented medium (see cell isolations) with 10 µl of a 10% suspension of FITC-labeled latex beads (Fluoresbrite plain YG 1.0 micron microspheres; Polysciences, Warrington, PA) in the presence or absence of 10^-8 M recombinant TSHß. Cells were recovered, microfuged briefly to remove unicorporated beads, and analyzed by flow cytometry. Because of the difference in the size of cells and beads, exclusion of residual nonincorporated beads was easily done by gating onto the dendritic cell population. For zymosan activation of dendritic cells, 2 x 10⁵ freshly isolated cells were cultured in 200 µl of supplemented medium with 0.0025% (w/v) zymosan (ICN Pharmaceuticals, Aurora, OH) in the presence or absence of 10^-8 M recombinant TSHß; supernatants were collected after 18 h and assayed for cytokine activity.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Immunoprecipitation of TSHr from intestinal lymphoid cells, thymocytes, and spleen cells

Cell lysates were prepared from lymphoid cells from the small intestine epithelium, from thymocytes, and from erythrocyte-depleted whole spleen cells. Immunoprecipitation and Western blot analyses were done using two anti-TSHr mAbs as described in Materials and Methods. Precipitation of the TSHr by this technique was confirmed using MTC-M cells which yielded a 95- to 100-kDa band characteristic of the mature glycosylated receptor protein (25) (Fig. 1). The 65- to 75-kDa band occasionally seen may reflect a subunit of the receptor protein (26, 27) or possibly nonglycosylated TSH receptor from cell lysates. As shown in Fig. 1A, TSHr-precipitated products were clearly evident in intestinal lymphoid cell preparations, confirming previous findings that the intestine is a site of high levels of TSHr expression (18). By comparison, TSHr-precipitated products were barely detectable in thymocyte lysates and were slightly more evident in spleen cell lysates (Fig. 1B). These findings were consistent in several immunoprecipitation experiments using different mouse strains.

View larger version (30K): [in this window] [in a new window]   FIGURE 1. Immunoprecipitation/Western blot analyses of TSHr from intraepithelial lymphocyte lysates (A) and whole thymocytes and spleen cell lysates (B). Precipitated products obtained from the MTC-M murine thyroid cell line are shown. Numbers to the left indicate the position of protein standards markers (kDa).

Experiments were done to determine whether the TSHr was expressed at low levels across all spleen cells or whether expression was linked to a particular cell subpopulation. Freshly isolated spleen cells were enriched for T cells, B cells, and dendritic cells. Fig. 2 shows the phenotypic profile of cells before and after enrichment, demonstrating 95.3% enrichment of T cells based on expression of CD4 and CD8, and 95.2% enrichment of B cells based on CD19 expression. In the dendritic cell fraction, 89.4% of the cells coexpressed CD11b and CD11c; 84.1% of the cells expressed MHC class II Ags, all of which are markers of splenic dendritic cells of the myeloid lineage (28, 29). T cell contamination of the dendritic cell-enriched fraction was <10% (Fig. 2); no contamination by B cells was observed (data not shown). Immunoprecipitation/Western blotting analyses of TSHr expression using those cells revealed minimal amounts of precipitated TSHr from B cells or T cells even after enrichment. Particularly noteworthy, however, was the finding that the TSHr was present at high levels in the dendritic cell fraction when compared with equivalent numbers of T cells and B cells (Fig. 3).

View larger version (54K): [in this window] [in a new window]   FIGURE 2. Phenotypic analyses of whole spleen cells before enrichment and after enrichment for T cells, B cells, and dendritic cells. Control staining by isotype-matched Abs are reflected by quadrant one (lower left) in two-color histograms and by the inflection mark in one-color histograms.

View larger version (43K): [in this window] [in a new window]   FIGURE 3. Immunoprecipitation/Western blot analyses of spleen cell fractions enriched for dendritic cells, T cells, and B cells as shown in Fig. 2. Numbers to the right indicate the position of protein standards (kDa).

View larger version (41K): [in this window] [in a new window]   FIGURE 4. A–F, Flow cytometric analyses of TSHr expression on splenic CD4+8- and CD4-8+ T cells, CD19-enriched B cells, CD5+ B cells, and CD11b+ splenic dendritic cells. G, Blocking of binding of biotin-labeled TSH to splenic dendritic cells using 10-4 M unlabeled recombinant TSH. H, Dose response of inhibition of TSH binding to splenic dendritic cells.

A subset of lymph node T cells express high levels of the TSHr

Expression of the TSHr was studied by flow cytometric analyses on lymph node-derived cells in a manner similar to that described for spleen cells. As shown in Fig. 5A, 52% of lymph node dendritic cells overall expressed the TSHr, further indicating that the presence of the TSH receptor is a feature of most dendritic cells in peripheral lymphoid tissues. A fascinating finding to emerge from these experiments, however, was the observation that unlike T cells in the spleen, a significant proportion of lymph node T cells including both CD4⁺8^- and CD4^-8⁺ cells expressed the TSHr at high levels (Fig. 5, B and C). The proportional expression of TSHr expression on lymph node B cells (Fig. 5, D–F) was similar to that for splenic B cells; binding of TSH to lymph node T cells was blocked with unlabeled recombinant TSH (data not shown).

View larger version (48K): [in this window] [in a new window]   FIGURE 5. Flow cytometric analyses of TSHr expression on lymph node CD11b+ dendritic cells, CD4+8- and CD4-8+ T cells, and lymph node CD19-enriched B cells and CD5+ B cells. Note the difference in TSHr expression on lymph node T cells compared with splenic T cells (Fig. 4).

View larger version (51K): [in this window] [in a new window]   FIGURE 6. Flow cytometric analyses of TSHr and TCRß expression (A) and TSHr and CD3 expression (B) on lymph node T cells. Expression of TSHr and CD4 or CD8 on lymph node T cells after treatment with anti-TSHr Ab in the absence of complement (C and E) and the presence of complement (D and F).

Three-color flow cytometric analyses were done to determine whether expression of the TSHr on lymph node T cells was associated with a specific lymphocyte subset based on the state of differentiation or according to properties which define functional characteristics. Lymph node cells were stained for TSHr expression in conjunction with CD45RB and CD4 and CD8. CD4⁺ and CD8⁺ T cells each consisted of two populations: a CD45RB^high subset that is considered to represent a population of naive nonmemory T cells, and a CD45RB^low subset believed to reflect memory T cells. As seen in Fig. 7, TSHr⁺ cells were almost exclusively associated with the CD45RB^high subset; few CD45RB^low cells were TSHr⁺.

View larger version (47K): [in this window] [in a new window]   FIGURE 7. Three-color staining for expression of TSHr on CD45RBhigh and CD45RBlow T cells. Note that TSHr+ T cells are exclusively expressed on the population of CD45RBhigh nonmemory T cells.

View larger version (25K): [in this window] [in a new window]   FIGURE 8. CD69 and TSHr expression on freshly isolated lymph node cells and on splenic T cells 48 h postactivation with anti-CD3 Ab, indicating that TSHr+ cells belong to a nonactivated T cell subset and that the TSHr is not acquired on T cells following activation via the TCR-CD3 complex.

View larger version (61K): [in this window] [in a new window]   FIGURE 9. Expression of CD11c and CD11b on dendritic cells from the spleen of day 18 fetal mice (A) and day 7 neonatal mice (C). Note the lower percentage of TSHr expression on cells at that time (B and C) compared with adult mice (Figs. 4 and 5).

The TSHr is a G protein-coupled receptor which when stimulated by TSH results in rapid increases in intracellular cAMP. To determine whether stimulation of the TSHr on dendritic cells results in a cAMP response, freshly isolated dendritic cells from C57BL/6 mice were cultured with titrated amounts of recombinant TSH, or with forskolin, a known inducer of cAMP activity. C.RFTshr^hyt/hyt mice, which are incapable of delivering a transmembrane signal due to a point mutation in the TSHr (30), were used as source of control dendritic cells. Note that the pattern of TSHr expression on immune cells from C.RFTSHr^hyt/hyt mice is similar to that observed for normal animals (data not shown). Shown in Fig. 10A, after 15 min of stimulation with TSH, intracellular cAMP levels in dendritic cells from normal mice were elevated significantly over unstimulated cultures in a dose-dependent manner and was approximately two-thirds of that induced by forskolin, thus confirming that the TSHr on murine hematopoietic cells are functionally active. Stimulation of dendritic cells from C.RFTshr^hyt/hyt mice, by comparison, failed to generate a cAMP signal (Fig. 10B).

View larger version (14K): [in this window] [in a new window]   FIGURE 10. Intracellular cAMP levels in freshly isolated splenic dendritic cells from C57BL/6 mice and C.RFTshrhyt/hyt mice cultured for 15 min in the absence of TSH, with 10-7–10-9 M TSH or 10-7 M forskolin. Data are mean values ± range for two experiments.

View larger version (51K): [in this window] [in a new window]   FIGURE 11. FITC-labeled latex bead uptake by untreated splenic dendritic cells (A and C) and TSH-treated dendritic cells (B and D) at 3 h (A and B) or 9 h (C and D) of in vitro culture.

View larger version (29K): [in this window] [in a new window]   FIGURE 12. Cytokine responses for IL-1ß (A), IL-12 (B), TNF- (C), and IL-6 (D) from 18-h zymosan-stimulated splenic dendritic cell cultures. Data are mean values ± SEM of two experiments; *, statistically significant difference (p < 0.05) using Student’s t test for unpaired observations.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

The observation of a strong association of TSHr expression with splenic and lymph node dendritic cells is of interest given the important role of those cells in immunity as seen by their ability to influence T cell and B cell activation, to elaborate cytokines used in the inflammatory response, and to serve as a bridge between the adaptive and the innate immune systems (36). This places a large proportion of the TSH-responsive cells of the immune system centrally within the activation/regulation process. In general, the TSHr⁺ dendritic cells identified here conform phenotypically to the myeloid dendritic cell subset based on expression of MHC class II and coexpression of CD11c and CD11b (25, 26, 37, 38). However, a number of additional dendritic cells markers, DEC-205, 33D1, CD8, c-kit, SCA-2, BP-1, and heat-stable Ag, now have been identified. Although information is incomplete regarding the extent to which those markers define discrete dendritic cell subsets, nonetheless differential expression of those markers has been linked to tissue-associated dendritic cell populations and to developmental differences of dendritic cells defined according to myeloid or lymphoid lineages (37, 38, 39, 40, 41). Within peripheral lymphoid tissues, DEC-205 appears to be expressed on most lymph node dendritic cells, but is present on only about half of the total splenic dendritic cells (37, 38). Conversely, CD8 distinguishes two splenic dendritic cell populations, whereas CD8 is expressed on a minor component of lymph node dendritic cells. Although in the present study the TSHr was expressed on a high proportion on both the splenic and lymph node dendritic cells, this was by no means a universal feature given that about 30–50% of the cells did not express the TSHr, thus indicating that the TSHr may serve to further delineate and characterize peripheral dendritic cell subpopulations.

Despite rapidly accumulating information about the phenotypic nature of dendritic cells, considerably less is known about the functional differences which exist between the various dendritic cell subsets. In general, however, professional APCs, including dendritic cells, are known to be important for Ag presentation and T cell priming, especially for the activation of naive T cells. For example, compared with the activational requirements of memory and effector T cells, the involvement of dendritic cells during naive T cell activation is particularly critical in terms of the time needed for optimal stimulation. This has been demonstrated in in vitro experiments in which effector T cells can be activated within hours of exposure to Ag by APCs, whereas naive T cells require a minimum of 12 h and possibly up to 30 h (42). The findings reported here of enhanced phagocytic activity of TSH-stimulated dendritic cells places TSH within the very earliest aspects of the immune response. Because resting dendritic cells are considerably more phagocytic than activated dendritic cells (43), a finding also borne-out in the present study by the greater degree of phagocytosis at 3 h vs 9 h after activation (Fig. 11), the effect of TSH appears to be either to prolong the initial state of phagocytosis by dendritic cells or to promote that response in a subset of otherwise nonphagocytic cells. The involvement of TSH in the regulation of dendritic cell cytokine secretion is likewise noteworthy. For example, IL-1 is critically involved in many aspects of both innate and adaptive immunity as seen by its ability to induce fever (44) and to serve as a costimulatory signal for T cells (45). Similarly, IL-12 synergistically enhances the production of other cytokines, in particular IFN-, a T_H1 cytokine with immune modulating (46) and antiviral and antibacterial activities (47).

Although the extent to which TSH participates in the immune response of TSHr⁺ lymph node T cells is not fully evident, TSH has been shown to influence the cellular composition and functional activities of cells of the immune system in a number of ways. C.RFTSHr^hyt/hyt mice, which produce but are unable to utilize TSH (30), have increased numbers of peripheral CD4⁺ T cells; this appears to be due to low numbers of CD8⁺ developing thymocytes (48). Interestingly, those animals also have skewed distributions of thymus-derived CD8⁺ T cell subsets in the gut epithelium (18). This suggests that CD8⁺ T cells are particularly susceptible to the effects of TSH, although additional studies will be needed to understand the significance of this in the overall context of immunity.

In mice, hormones, including TSH, have been shown to enhance cytokine responses of hematopoietic cells (31, 49) to increase the cytotoxic activity of NK cells (50) and to serve as a costimulatory factors for mitogen or IL-2-induced T cell proliferation (50). However, because in the latter experiments TSH resulted in increases in proliferation of only about 25–50%, it appears that the costimulatory effects are directed to a subset of the total T cell population, most likely the TSHr⁺ cells described here for the lymph nodes and to a lesser extent the spleen. This also would be consistent with the awareness that signaling by costimulatory molecules such as CD28, as well as the CD4 and CD8 coreceptors, are more critical for optimal activation of naive T cells than for memory cells (51, 52, 53). In that vein also, it is interesting that distinct patterns of cytokine production exist among T cells as a function of CD45RB expression, as shown in a study demonstrating that T_H2 cytokines were produced principally by CD45RB^low cells, whereas T_H1 cytokines were produced by CD45RB^high cells in response to parasitic infections (54). Experiments are currently underway to examine the functional differences between TSHr⁺ T cells in normal C.RF mice and radiation chimeras made from nonmutant C.RF mice reconstituted with bone marrow stem cells from C.RFTshr^hyt/hyt mice.

The possibility exists that the primary source of TSH for the immune system is not the pituitary but that it is produced by cells of the immune system itself or by cells intimately associated with lymphoid tissues. Mechanisms for this have been proposed (55) and evidence for this has been demonstrated in the intestinal immune system (18) and in studies showing that TSH can be produced by human monocytic cells (14). The extent to which TRH is also involved in the regulation of this response has not been unequivocally determined; however, the TRH precursor peptide (TRH-Gly) has been reported within the spleen (56). In fact, of 14 non-neural tissues examined in the latter study, the small intestine duodenum and the spleen ranked second and third highest in terms of the concentration of TRH-Gly per milligram of tissue weight (56). This indicates that under normal conditions metabolically active TRH can be converted from existing stores of posttranslational TRH-Gly precursors, thus establishing a mechanism for the rapid secretion of TRH. Still to be understood in this scenario is the precise cell population(s) involved in TRH production, and the nature of the inductive signal for TRH-Gly conversion to TRH; i.e., whether it is mediated by external Ag-driven stimuli or whether signals from the host "feed in" during the early phase of the immune-endocrine process. Some evidence for an internal signal currently exists from experiments which demonstrate increased TRH-Gly levels following thyroid hormone (T₃ or T₄) stimulation (57). Additional studies aimed at delineating the participation of TRH and other peptide mediators can be done using the hormone-responsive cells described here to understand the functional involvement of immune-endocrine interactions on the immune response.

	Acknowledgments

 
We thank Michael Whetsell for technical assistance.

	Footnotes

 
¹ This work was supported by National Institutes of Health Grant DK35566 and by a grant from the Oklahoma Center for the Advancement of Science and Technology.

² Address correspondence and reprint requests to Dr. John R. Klein at his current address: Department of Basic Sciences, Dental Branch, University of Texas Health Science Center, 6515 John Freeman Avenue, Houston, TX 77030.

³ Abbreviations used in this paper: HPT, hypothalamus-pituitary-thyroid; TRH, thyrotropin-releasing hormone; TSH, thyroid-stimulating hormone (thyrotropin); TSHr, TSH receptor.

Received for publication December 13, 1999. Accepted for publication March 29, 2000.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

1. Wilder, R. L.. 1995. Neuroendocrine-immune system interactions and autoimmunity. Annu. Rev. Immunol. 13:307.[Medline]
2. Beisel, W. R., M. I. Rapoport. 1969. Inter-relations between adrenocortical functions and infectious illness. N. Engl. J. Med. 280:696.
3. Claman, H. N.. 1975. How corticosteroids work. J. Allergy Clin. Immunol. 55:145.[Medline]
4. Terr, A. I.. 1994. Immunologic therapy. , , , ed. Basic and Clinical Immunology 8th Ed.715. Appleton and Lang, Norwalk, CT.
5. Patibandla, S. A., B. S. Prabhakar. 1996. Autoimmunity to the thyroid stimulating hormone receptor. Adv. Neuroimmunol. 6:347.[Medline]
6. Dardenne, M., W. Savino, J.-F. Bach. 1988. Modulation of thymic endocrine function by thyroid and steroid hormones. Int. J. Neurosci. 39:325.[Medline]
7. Dubius, J.-M., J.-M. Dayer, C. A. Siegrist-Kaiser, A. G. Burger. 1988. Human recombinant interleukin-1ß decreases plasma thyroid hormone and thyroid stimulating hormone levels in rats. Endocrinology 123:2175.[Abstract]
8. Fabris, N., E. Mocchegiani, S. Mariotti, F. Pacini, A. Pinchera. 1989. Thyroid-thymus interactions during development and aging. Horm. Res. 31:85.[Medline]
9. Ajjan, R. A., P. F. Watson, A. P. Weetman. 1996. Cytokines and thyroid function. Adv. Neuroimmunol. 6:359.[Medline]
10. Raiden, S., E. Polack, V. Nahmod, M. Labeur, F. Holsboer, E. Artz. 1995. TRH receptor on immune cells: In vitro and in vivo stimulation of human lymphocyte and splenocyte DNA synthesis by TRH. J. Clin. Immunol. 15:242.[Medline]
11. Harbour, D. V., T. E. Kruger, D. Coppenhaver, E. M. Smith, W. J. Meyer. 1989. Differential expression and regulation of thyrotropin (TSH) in T cells lines. Mol. Cell. Endorinol. 64:229.[Medline]
12. Kruger, T. E., J. E. Blalock. 1986. Cellular requirements for thyrotropin enhancement of in vitro antibody production. J. Immunol. 137:197.[Abstract]
13. Kruger, T. E., L. R. Smith, D. V. Harbour, J. E. Blalock. 1989. Thyrotropin: An endogenous regulator of the in vitro immune response. J. Immunol. 142:744.[Abstract]
14. Coutelier, J.-P., J. H. Kehrl, S. S. Bellur, L. D. Kohn, A. L. Notkins, B. S. Prabhakar. 1990. Binding and functional effects of thyroid stimulating hormone on human immune cells. J. Clin. Immunol. 10:204.[Medline]
15. Wang, J., J. R. Klein. 1994. Thymus-neuroendocrine interactions in extrathymic T cells development. Science 265:1860.[Abstract/Free Full Text]
16. Wang, J., J. R. Klein. 1995. Hormone regulation of extrathymic gut T cell development: Involvement of thyroid stimulating hormone. Cell. Immunol. 161:299.[Medline]
17. Wang, J., J. R. Klein. 1996. Hormone regulation of murine T cells: potent tissue-specific immunosuppressive effects of thyroxine targeted to gut T cells. Int. Immunol. 8:231.[Abstract/Free Full Text]
18. Wang, J., M. Whetsell, J. R. Klein. 1997. Local hormone networks and intestinal T cells homeostasis. Science 275:1937.[Abstract/Free Full Text]
19. Mosley, R. L., J. R. Klein. 1992. A rapid method for isolating murine intestine intraepithelial lymphocytes with high yield and purity. J. Immunol. Methods 156:19.[Medline]
20. Jaiswal, A. I., C. Dubey, S. L. Swain, M. Croft. 1996. Regulation of CD40 ligand expression on naïve CD4 T cells: A role for TCR but not costimulatory signals. Int. Immunol. 8:275.[Abstract/Free Full Text]
21. Croft, M., S. D. Joseph, K. T. Miner. 1997. Partial activation of naive CD4 T cells and tolerance induction in response to peptide presented by resting B cells. J. Immunol. 159:3257.[Abstract]
22. Ridge, J. P., J. F. Ephraim, P. Matzinger. 1996. Neonatal tolerance revisited: turning on newborn T cells with dendritic cells. Science 271:1723.[Abstract]
23. Seetharamaiah, G. S., N. M. Wagle, J. C. Morris, B. S. Prabhakar. 1995. Generation and characterization of monoclonal antibodies to the human thyrotropin (TSH) receptor: Antibodies can bind to discrete conformational or linear epitopes and block TSH binding. Endocrinology 136:2817.[Abstract]
24. Randolph, G. J., S. Beaulieu, S. Lebecque, R. M. Steinman, W. A. Muller. 1998. Differentiation of monocytes into dendritic cells in a model of transendothelial trafficking. Science 282:480.[Abstract/Free Full Text]
25. Harfts, E., M. S. Ross, S. S. Nussey, A. P. Johnstone. 1994. Production of antibodies to the human thyrotropin receptor and their use in characterizing eukaryotic expressed functional receptor. Mol. Cell. Endorinol. 102:77.[Medline]
26. Loosfelt, H., C. Pichon, A. Jolivet, M. Misrahi, B. Caillou, M. Jamous, B. Vannier, E. Milgrom. 1992. Two-subunit structures of the human thyrotropin receptor. Proc. Natl. Acad. Sci. USA 89:3765.[Abstract/Free Full Text]
27. Misrahi, M., N. Ghinea, S. Sar, B. Saunier, A. Jolivet, H. Loosfelt, M. Cerutti, G. Devauchells, E. Milgrom. 1994. Processing of the precursors of the human thyroid-stimulating hormone receptor in various eukaryotic cells (human thyrocytes, transfected L cells, and baculovirus-infected insect cells). Eur. J. Biochem. 222:711.[Medline]
28. Kato, T., H. Yamane, H. Nariuchi. 1997. Differential effects of LPS and CD40 ligand stimulations on the induction of IL-12 production by dendritic cells and macrophages. Cell. Immunol. 181:59.[Medline]
29. Liu, L., H.-H. Zhang, C. Jenkins, G. G. MacPherson. 1998. Dendritic cell heterogeneity in vivo: Two functionally different dendritic cell populations in rat intestinal lymph can be distinguished by CD4 expression. J. Immunol. 161:1146.[Abstract/Free Full Text]
30. Biesiada, E., P. M. Adams, D. R. Shanklin, G. S. Bloom, S. A. Stein. 1996. Biology of the congentially hypothyroid hyt/hyt mouse. Adv. Neuroimmunol. 6:309.[Medline]
31. Whetsell, M., E. U. Bagriacik, G. S. Seetharamaiah, B. S. Prabhakar, J. R. Klein. 1999. Neuroendocrine-induced synthesis of bone marrow-derived cytokines with inflammatory immunomodulating properties. Cell. Immunol. 192:159.[Medline]
32. Pierpaoli, W., E. Sorkin. 1972. Hormones, thymus and lymphocyte function. Specialia 15:1385.
33. Pierpaoli, W., H. G. Kopp, J. Muller, M. Keller. 1977. Interdependence between neuroendocrine programming and the generation of immune recognition in ontogeny. Cell. Immunol. 29:16.[Medline]
34. Pekonen, F., B. D. Weintraub. 1978. Thyrotropin binding to cultured lymphocytes and thyroid cells. Endocrinology 103:1668.[Abstract]
35. Harbour, D.V., S. Leon, C. Keating, T. K. Hughes. 1990. Thyrotropin modulates B-cell function through specific bioactive receptors. Prog. Neuroendocrinol. 3:266.
36. Steinman, R. M.. 1999. Dendritic cells. , ed. Fundamental Immunology 4th Ed.547. Lippincott-Raven, New York.
37. Maraskovsky, E., B. Pulendran, K. Shortman. 1999. Lymphoid-related dendritic cells. , , ed. Dendritic Cells 93. Academic, San Diego.
38. Vremec, D., K. Shortman. 1997. Dendritic cell subtypes in mouse lymphoid organs: Cross-correlation of surface markers, changes with incubation, and differences among thymus, spleen, and lymph nodes. J. Immunol. 159:565.[Abstract]
39. Inaba, K., M. Inaba, M. Deguchi, K. Hagi, R. Yasumizu, S. Ikehara, S. Muramatsu, R. M. Steinman. 1993. Granulocytes, macrophages, and dendritic cells arise from a common major histocompatibility complex class II-negative progenitor in mouse bone marrow. Proc. Natl. Acad. Sci. USA 90:3038.[Abstract/Free Full Text]
40. Ardavin, C. L., C. Wu, K. Shortman. 1993. Thymic dendritic cells and T cells develop simultaneously within the thymus from a common precursor population. Nature 362:761.[Medline]
41. de St. Groth, B. F.. 1998. The evolution of self-tolerance: A new cell arises to meet the challenge of self-reactivity. Immunol. Today 19:448.[Medline]
42. Iezzi, G., K. Karalainen, A. Lanzavecchia. 1998. The duration of antigenic stimulation determines the fate of naive and effector T cells. Immunity 8:89.[Medline]
43. Rescigno, M., M. Rittig, S. Citterio, M. K. Matyszak, M. Foti, F. Granucci, M. Martino, U. Fascio, P. Rovere, P. Ricciardi-Castagnoli. 1999. Interaction of dendritic cells with bacteria. , , ed. Dendritic Cells 407. Academic, New York.
44. Janeway, C. A., P. Travers, M. Walport, and D. J. Capra. Immunobiology: The Immune System in Health and Disease, 4th Ed. Garland Press, New York, p. 383.
45. Huber, M., H. U. Beuscher, P. Rohwer, R. Kurrle, M. Rollinghoff, M. Lohoff. 1998. Costimulation via TCR and IL-1 receptor reveals a novel IL-1-mediated autocrine pathway of Th2 cell proliferation. J. Immunol. 160:4242.[Abstract/Free Full Text]
46. Fukao, T., S. Matsuda, S. Koyasu. 2000. Synergistic effects of IL-4 and IL-18 on IL-12- dependent IFN- production by dendritic cells. J. Immunol. 164:64.[Abstract/Free Full Text]
47. Gallin, J. I., J. M. Farber, S. M. Holland, T. B. Nutman. 1995. Interferon- in the management of infectious diseases. Ann. Intern. Med. 123:216.[Abstract/Free Full Text]
48. Erf, G. F.. 1993. Immune development in young-adult C.RF-hyt mice is affected by congenital and maternal hypothyroidism. Proc. Soc. Exp. Biol. Med. 204:40.[Abstract]
49. Delgado, M., E. J. Munoz-Elias, Y. Kan, I. Gozes, M. Fridkin, D. E. Brenneman, R. P. Gomariz, D. Ganea. 1998. Vasoactive intestinal peptide and pituitary adenylate cyclase-activating polypeptide inhibit tumor necrosis factor transcriptional activation by regulating nuclear factor-B and cAMP response element-binding protein/c-Jun. J. Biol. Chem. 20:31427.
50. Provinciali, M., G. DiStefano, N. Fabris. 1992. Improvement in the proliferative capacity and natural killer cell activity of murine spleen lymphocytes by thyrotropin. Int. J. Immunopharmacol. 14:865.[Medline]
51. Lenschow, D. J., T. L. Walunas, J. A. Bluestone. 1996. CD28/B7 system of T cell costimulation. Annu. Rev. Immunol. 14:233.[Medline]
52. Viola, A., M. Salio, L. Tuosto, S. Linkert, O. Acuto, A. Lanzavecchia. 1997. Quantitative contribution of CD4 and CD8 to T cell antigen receptor serial triggering. J. Exp. Med. 186:1775.[Abstract/Free Full Text]
53. Zinkernagel, R. M., M. F. Bachmann, T. M. Kundig, S. Oehen, H. Pirchet, H. Hengartner. 1996. On immunological memory. Annu. Rev. Immunol. 14:333.[Medline]
54. Powrie, F., R. Correa-Oliveira, S. Mauze, R. L. Coffman. 1994. Regulatory interactions between CD45RB^high and CD45RB^low CD4⁺ T cells are important for the balance between protective and pathogenic cell-mediated immunity. J. Exp. Med. 179:589.[Abstract/Free Full Text]
55. Klein, J. R.. 1998. Hormone regulation of immune homeostasis: local or long distance?. Biochem. Pharmacol. 56:1.[Medline]
56. Fuse, Y., D. H. Polk, R. W. Lam, D. A. Fisher. 1990. Distribution of thyrotropin-releasing hormone (TRH) and precursor peptide (TRH-Gly) in adult rat tissues. Endocrinology 127:2501.[Abstract]
57. Simard, M., A. E. Pekary, V. P. Smith, J. M. Hershman. 1989. Thyroid hormones modulate thyrotropin-releasing hormone biosynthesis in tissues outside the hypothalamic-pituitary axis of male rate. Endocrinology 125:524.[Abstract]

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