Pig Thyrocytes Research Articles

The cytochemistry of anaplastic thyroid tumour cells and differentiated thyrocytes analyzed by TOF-SIMS and depth profiling

The depth profiling procedure was utilized to compare the chemistry of anaplastic thyroid tumour cells SW1736 with that of primary cultured pig thyrocytes. Sputtering was performed with SF 5 + and C 60 + as primary ions and Bi 3 + was used as primary ion for the analysis. The spectra from cells prior to sputtering, representing the cell surface chemistry, showed similar distribution patterns and intensity ratios. However, the peaks representing cholesterol signal and lipoxin were significantly higher in the tumour cell samples. The spectra from sputtered samples, representing intracellular chemistry, showed a significant decrease in the number of detectable peaks, especially after sputtering with SF 5 +. Sputtering conditions must be further developed to make the technique useful for detailed analysis of cells.

Amiodarone Inhibits Thyroidal Iodide Transportin Vitroby a Cyclic Adenosine 5′-Monophosphate- and Iodine-Independent Mechanism

Thyroid side effects are common in patients treated for cardiac arrhythmias with amiodarone (AM). A major disturbance is inhibited thyroidal radioiodine uptake in AM-induced thyrotoxicosis, which makes 131I therapy ineffective. On the other hand, failure to escape from the Wolff-Chaikoff effect by down-regulation of the sodium/iodide symporter (NIS) is proposed to explain AM-induced hypothyroidism. However, previously no experimental studies on the possible mechanisms have been conducted. We therefore investigated the early effects of AM on thyroidal iodide transport using bicameral chamber cultures of primary pig thyrocytes that reproduce the three tissue compartments (epithelium, lumen, and extrafollicular space) of the gland. AM dose-dependently (1-50 microm) inhibited the TSH-stimulated transepithelial (basal to apical) transport of 125I- by up to 90%. The inhibitory effect was noticed already after 8 h and was further pronounced after 1-4 d, depending on the AM concentration. The intracellularly accumulated 125I- was reduced by perchlorate but not AM, and quantitative real-time RT-PCR revealed no change in the NIS expression in AM-treated cells. Blocking of cAMP degradation with 3-isobutyl-1-methylxanthine or withdrawal of AM reversed AM-induced changes in electrolyte transport but were unable to recover the suppressed 125I- transport. The iodine-free AM analog dronedarone also inhibited 125I- transport to the same extent as AM. The findings indicate that AM blocks thyroidal iodide uptake by reducing the iodide permeability of the apical plasma membrane of the thyroid epithelial cells. The effect is iodine independent and long-lasting and does not involve impaired function of NIS or the TSH receptor/cAMP signaling pathway.

Selenium has a protective role in caspase-3-dependent apoptosis induced by H2O2 in primary cultured pig thyrocytes.

Hydrogen peroxide (H2O2), necessary for thyroid hormonogenesis, is produced at the apical surface of the thyroid follicular epithelium. Excess H2O2 is potentially cytotoxic and may contribute to the development of hypothyroidism, e.g. in severe selenium deficiency. Yet it is unclear how H2O2 contributes to thyroid cell death. H2O2-induced apoptosis and necrosis were studied in primary cultured pig thyroid cells. Glutathione peroxidase (GPx) activity was altered by culture in low serum with or without selenite substitution. Apoptosis was evaluated by spectrofluorometric measurement of caspase-3-specific substrate cleavage, and by analysis of DNA fragmentation by agarose gel electrophoresis. Necrosis was detected by 51Cr release from prelabeled cells. Exogenous H2O2 dose-dependently (100-400 micromol/l) activated caspase-3 within 3-12 h, and DNA degradation was observed after 24 h. The potency of H2O2 to induce apoptosis was low compared with that of staurosporine, a strong proapoptotic agent. H2O2-treated cells with reduced GPx activity showed increased caspase-3 activation. Incubation of serum-starved cells with selenite (10-100 nmol/l) normalized the GPx activity and reduced the activation of caspase-3 by H2O2. High H2O2 concentrations (400-800 micromol/l) were required to obtain necrosis. The H2O2-induced necrosis was exaggerated by both low GPx activity and catalase inhibition. Cytotoxic effects of H2O2 on thyroid cells include caspase-3-dependent apoptosis that occurs at H2O2 concentrations insufficient to induce necrosis. Selenium deficiency aggravates the apoptotic response, probably due to impaired capacity of GPx to degrade H2O2.

Effect of iodide on nicotinamide adenine dinucleotide phosphate oxidase activity and Duox2 protein expression in isolated porcine thyroid follicles.

Thyroperoxidase requires H(2)O(2) to catalyze the biosynthesis of thyroxine residues on thyroglobulin. Iodide inhibits the generation of H(2)O(2), and consequently the synthesis of thyroid hormones (Wolff-Chaikoff effect). The H(2)O(2) generator is a calcium-dependent nicotinamide adenine dinucleotide phosphate (NADPH) oxidase involving the flavoprotein Duox2. NADPH oxidase activity and Duox2 require cAMP to be expressed in pig thyrocytes. We studied the effect of iodide on NADPH oxidase activity, the DUOX2 gene, and Duox2 protein expression in pig thyroid follicles cultured for 48 h with forskolin or a cAMP analog. Iodide inhibited the cellular release of H(2)O(2) and NADPH oxidase activity, effects prevented by methimazole. Northern blot studies showed that iodide did not reduce DUOX2 mRNA levels but did reduce those of TPO and NIS. Western blot analyses using a Duox2-specific antipeptide showed that Duox2 has two N-glycosylation states, which have oligosaccharide motifs accounting for about 15 kDa and 25 kDa, respectively, of the apparent molecular mass. Cyclic AMP increased the amount of the highly glycosylated form of Duox2, an effect antagonized by iodide in a methimazole-dependent manner. These data suggest that an oxidized form of iodide inhibits the H(2)O(2) generator at a posttranscriptional level by reducing the availability of the mature Duox2 protein.

Transforming growth factor-beta and epidermal growth factor synergistically stimulate epithelial to mesenchymal transition (EMT) through a MEK-dependent mechanism in primary cultured pig thyrocytes.

Enhancement of tumor cell growth and invasiveness by transforming growth factor-beta (TGF-beta) requires constitutive activation of the ras/MAPK pathway. Here we have investigated how MEK activation by epidermal growth factor (EGF) influences the response of fully differentiated and growth-arrested pig thyroid epithelial cells in primary culture to TGF-beta1. The epithelial tightness was maintained after single stimulation with EGF or TGF-beta1 (both 10 ng/ml) for 48 hours. In contrast, co-stimulation abolished the transepithelial resistance and increased the paracellular flux of [(3)H]inulin within 24 hours. Reduced levels of the tight junction proteins claudin-1 and occludin accompanied the loss of barrier function. N-cadherin, expressed only in few cells of untreated or single-stimulated cultures, was at the same time increased 30-fold and co-localised with E-cadherin at adherens junctions in all cells. After 48 hours of co-stimulation, both E- and N-cadherin were downregulated and the cells attained a fibroblast-like morphology and formed multilayers. TGF-beta1 only partially inhibited EGF-induced Erk phosphorylation. The MEK inhibitor U0126 prevented residual Erk phosphorylation and abrogated the synergistic responses to TGF-beta1 and EGF. The observations indicate that concomitant growth factor-induced MEK activation is necessary for TGF-beta1 to convert normal thyroid epithelial cells to a mesenchymal phenotype.

Formation of three-dimensional thyroid follicle-like structures by polarized FRT cells made communication competent by transfection and stable expression of the connexin-32 gene.

Pig thyrocytes, either in the intact gland or cultured under conditions leading to thyroid follicle reconstitution, coexpress two gap junction proteins, connexin-32 (Cx32) and connexin-43 (Cx43). As thyrocytes cultured in the form of a monolayer only express Cx43, we hypothesized that Cx32 could play a role in thyroid folliculogenesis. In the present work, we analyzed the ability of polarized FRT cells (that are gap junction deficient) to form follicle-like structures after stable transfection with either Cx32 or Cx43 genes. Wild-type and transfected FRT cells, while growing, showed the capacity to form three-dimensional structures corresponding to domes that result from the accumulation of fluid underneath limited areas of the cell layer. The number of domes formed by FRT cells expressing Cx32 (FRT-Cx32) was 2- to 3-fold higher than that obtained with either wild-type or Cx43-transfected FRT cells (FRT-Cx43). Domes generated by FRT-Cx32 cells were stable (beyond 3 weeks of culture), whereas those formed from wild-type or FRT-Cx43 cells were transient, disappearing when cells reached confluence. Inspection of the cell organization within domes formed from FRT-Cx32 cells by phase contrast and confocal microscopy revealed a progressive transition from domes toward closed structures with a lumen. The tightness of the lumen was demonstrated by the retention of a fluorescent probe, lucifer yellow, introduced by microinjection. Electron microscope examinations showed that the neoformed follicle-like structures had an inside-out polarity. Analyses of cell motion and division with time, by fluorescence video microscopy, indicated that the transformation of domes into inside-out follicles brings into play the migration of cells and, to a lesser extent, cell multiplication underneath the domes. In conclusion, FRT cells forced to express Cx32 give rise to domes that transform into closed inside-out follicles. This gain of function appears Cx specific, as FRT-Cx43 cells did not form similar structures. Our data suggest that the formation and/or functioning of Cx32 gap junctions might represent a key event in thyroid epithelium morphogenesis, i.e. formation of a lumen from a tight epithelial cell layer.

PROTEOLYTIC ACTIVITY IN INTACT SHEETS OF POLARIZED EPITHELIAL CELLS AS DETERMINED BY A CELL-PERMEABLE FLUOROGENIC SUBSTRATE

The purpose of the present investigation was to develop a system for continuous evaluation of extralysosomal proteolytic activity and its regulation in polarized epithelial cells. Filter inserts containing a tight monolayer of primary cultured pig thyrocytes were placed in a thermostated aluminium block. The cell-permeable, fluorogenic calpain and proteasome substrate succinyl-Leu-Leu-Val-Tyr-7-amino-4-methylcoumarin was added to the apical buffer and fluorescence changes were continuously measured via the fibre optics of a luminometer held at a fixed distance from the cell layer. Basal proteolytic activity was reduced by 60–70% by the proteasome inhibitor lactacystin. Proteolysis was increased within a few minutes after application of Ca2+-mobilizing agents (ionomycin, 4-bromo-A23187, thapsigargin and maitotoxin). Forskolin and staurosporine also enhanced the proteolytic activity. We conclude that Ca2+mobilization, and possibly also changes of protein kinase activity, rapidly increase non-lysosomal proteolysis in the intact thyroid epithelium.

Deactivation of TSH receptor signaling in filter-cultured pig thyroid epithelial cells.

Thyrotropin [thyroid-stimulating hormone (TSH)] receptor on-off signaling was studied in polarized monolayers of pig thyrocytes cultured on permeable support. Transepithelial resistance (R) and potential difference (PD) were used as parameters to monitor the effect of altered TSH concentrations on vectorial electrolyte transport. TSH induced rapid but long-lasting changes in R (decrease) and PD (increase) that were cAMP-dependent and related to enhanced transcellular conductance of sodium and chloride. Withdrawal of TSH from cultures prestimulated with TSH (0.1 mU/ml) for 48 h resulted in restitution of R to control level within 30 min. Such deactivation was markedly accelerated by mild trypsinization, which degraded receptor-bound ligand without affecting TSH receptor responsiveness or ion transporting capacity. Small alterations in the TSH concentration (0.01-0.1 mU/ml) were followed almost instantaneously by adjustments of R. In contrast, the reversal of R after acute TSH stimulation (30 min) and subsequent TSH washout was delayed for several hours independently of cell surface trypsinization. The observations indicate that, during continuous exposure to physiological concentrations, TSH exerts a close minute-to-minute surveillance of thyroid function and the rate-limiting step of deactivation is the dissociation of ligand from the TSH receptor at the cell surface. TSH-deprived cells briefly exposed to TSH are refractory to rapid deactivation, probably because of altered metabolism downstream of TSH receptor signal transduction.

Biochemical characterization of a Ca 2+/NAD(P)H-dependent H 2O 2 generator in human thyroid tissue

An NAD(P)H-dependent H 2O 2 forming activity has been evidenced in thyroid tissue from patients with Grave's disease. Its biochemical properties were compared to those of the NADPH oxidase previously described in pig thyroid gland. Both were Ca 2+-dependent and activated by inorganic phosphate anions in the same range of concentrations. Both are flavoproteins using FAD as cofactor, but the human enzyme was also able to utilize FMN. The apparent K m for NADPH of the human enzyme (100 μM) was 5–10 times higher than that of porcine enzyme. V m was 3 to 10 times higher in pig (150 nmol × h -1 × mg -1) than in man (14 to 45). Total content in human tissue was 7 to 9% of that in porcine tissue. An unidentified inhibitor has been detected in the 3000 g particulate fraction from most patients, which could account for this apparently low enzyme content. An NADH-dependent H 2O 2 production has also been observed in porcine and human thyroid tissues. This activity was only partly Ca 2+-dependent (man, 50–70%; pig, 80–90%) and presented similar apparent K m values for NADH (man, 100 μM; pig, 200 μM). In pig thyrocytes, the expression of the Ca 2+-dependent part of the NADH-oxidase activity was induced by TSH and down-regulated by TGFβ, as was the NADPH oxidase activity. Furthermore, NADPH and NADH-dependent activities were not additive. We conclude that a single, inducible, NAD(P)H-oxidase can use NADPH or NADH as substrate to catalyse H 2O 2 formation, and that human and porcine NAD(P)H-oxidases are highly similar. Differences observed could be attributed to minor differences in enzyme structure and/or in membrane microenvironment. The NADH-dependent Ca 2+-independent activity observed in human and porcine thyroid fractions could be attributed to a distinct and constitutive enzyme.

Activation by thyroid stimulating hormone of nerve growth factor-induced gene-B expression in thyrocytes in culture: relation with proliferation and specific gene expression

Nerve growth factor-induced gene-B (NGFI-B) is an immediate early gene first found as a part of the PC12 cell response to NGF (Milbrandt, J., Science 238 (1987) 797–799). We have previously reported that NGFI-B mRNA is strongly upregulated by thyroid-stimulating hormone (TSH) in dog thyrocytes in culture (Pichon et al., Endocrinology 137 (1996) 4691–4698). In this study, we have analyzed the regulation of NGFI-B mRNA expression by a variety of agents acting on thyrocytes proliferation and/or differentiation. We show that: (1) the induction of NGFI-B mRNA is stronger after stimulation of the cAMP cascade, but it is not restricted to this signaling pathway; (2) the powerful mitogens for thyroid cells EGF and HGF have little or no effect on NGFI-B mRNA induction; (3) NGFI-B mRNA is induced by anisomycin at a subinhibitory concentration for protein synthesis, and is superinduced by the combination of TSH and anisomycin; this treatment decreases the TSH-induced proliferation levels, but does not inhibit the induction of some differentiation markers; and (4) both in dog and in pig thyrocytes, NGFI-B mRNA induction is observed after a variety of treatments stimulating differentiation, but without proliferative effects. Our results therefore suggest that NGFI-B mRNA induction might not be related to TSH-induced thyrocyte proliferation, but could participate in the differentiation program triggered by TSH.

H2O2 induces apoptosis of pig thyrocytes in culture.

Apoptosis might be involved in the reduction of the thyroid cell population in physiopathological situations such as goitre involution and autoimmune deleterious processes. Up to now, little attention has been paid to the apoptotic phenomenon in the normal thyroid gland the specialized metabolism of which is expected to generate reactive oxygen species. Indeed, thyroid cells have the capacity to synthesize H2O2. In this study, we have analyzed the capacity of H2O2 to trigger apoptosis of pig thyrocytes in culture to try to determine whether thyrocytes exhibit a particular resistance to apoptosis induced by an oxidative stress. We show that exposure of thyrocytes cultured as monolayers to exogenous H2O2 induced cell death with characteristics of apoptosis. The effect of H2O2 was concentration-dependent; apoptotic cells were already observed after exposure to 50 micro M H2O2. At high concentrations (millimolar range), H2O2 exerted toxic effects leading to rapid cell disruption. Within the first hour after the onset of exposure to 50-300 micro M H2O2, early signs of apoptosis, i.e. DNA fragmentation, appeared in a low (0.1-1%) but definite fraction of thyrocytes. The proportion of adherent cells exhibiting DNA fragmentation remained fairly constant after 6, 15 and 24 h. During the 24-h period, an increasing number of cells detached from the culture dish and up to 30-40% of cells in suspension displayed apoptotic features. The fraction of cells that lost contact with the culture dish amounted to up to 25% 24 h after addition of 300 micro M H2O2. In conclusion, as reported for other cell types, low H2O2 concentrations are capable of triggering apoptosis in thyrocytes cultured as monolayers. Thyrocytes that undergo apoptosis secondarily lose contact with neighbour cells and the substratum; cell detachment from the monolayer probably happens within 1-2 h after initiation of DNA fragmentation. Our data show that the apoptotic commitment can take place many hours after initiation of the oxidative stress.

Effects of insulin-like growth factor I on growth, epithelial barrier and iodide transport in polarized pig thyrocyte monolayers.

The effects of insulin-like growth factor I (IGF-I) on mitogenesis, epithelial barrier function and transepithelial iodide transport were studied in confluent, polarized monolayers of pig thyrocytes cultured on filter in Transwell bicameral chambers. The growth rate in controls cultured in 1% fetal calf serum was low. Insulin-like growth factor I stimulated dose-dependently the incorporation of [3H]thymidine, maximally at 100 ng/ml, which corresponded to an increase of DNA content by 60% after 6 days. Thyrotropin (1 mU/ml) alone did not stimulate cell multiplication but inhibited partially the stimulatory effect of IGF-I. Insulin-like growth factor I (100 ng/ml) increased within 10 min the transepithelial potential difference, which remained elevated for several days, but did not significantly change the transepithelial resistance. When added together, IGF-I reinforced the effects of TSH on potential difference (increase) and resistance (decrease). A preserved epithelial barrier in IGF-I-treated cultures was confirmed by observing a normal immunolocalization of the tight junction protein ZO-1 and an unchanged ultrastructure of the junctional complex. Insulin-like growth factor I increased the transepithelial flux of 125I- in the basal-to-apical, but not in the opposite, direction. Stimulation of iodide transport by IGF-I was modest after 2 days and pronounced after 6 days. In comparison, TSH-stimulated iodide transport was higher after 2 days but lower after 6 days. Both TSH and IGF-I were strongly synergistic, after 6 days amounting to a 90-fold increase over the control basoapical 125I- transfer. The simultaneous accumulation of 125I- in the cell layer was increased two- to fourfold by IGF-I and/or TSH. In conclusion, IGF-I is able to induce growth in preformed monolayers of pig thyrocytes cultured on permeable filter. During these conditions, the mitogenic effect of IGF-I is partially inhibited by TSH, which has no growth-promoting action on its own. The transepithelial transport of iodide and bulk electrolytes is altered by IGF-I without affecting the epithelial barrier function. Specifically, IGF-I up-regulates the activity of the basolateral iodide pump and increases the iodide permeability of the apical plasma membrane. The action of IGF-I on iodide transport is independent of, although synergistic with, that of TSH. The findings support the notion that IGF-I may be an important regulator of thyroid growth and differentiated functions.

Analysis of the functional state of T 3 nuclear receptors expressed in thyroid cells

T 3 nuclear receptors (TR) are present in thyroid cells. We have analyzed the ability of thyroid TR to function as transcriptional regulators. Studies were performed on pig thyrocytes in primary culture. Messenger RNA corresponding to TR α 1, α 2 and β were detected in pig thyrocytes by RT-PCR and Northern blot; the α 2 mRNA was more abundant than the α 1 mRNA. Thyrocytes were transiently transfected with different plasmids containing the CAT (chloramphenicol acetyl transferase) gene placed under the control of different promoters (ΔMTV, TK or ΔSV 40) and bearing a thyroid hormone response element, TREp or TRE DR + 4. It was found that TSH induced a concentration-dependant increase of the transfection efficiency, an effect reproduced by (Bu) 2cAMP and Forskolin. Cells transfected with either ΔMTV-, TK- or ΔSV 40-TREp-CAT expressed similar basal CAT activities. Addition of T 3 produced a 3-fold increase of CAT activity expressed from each of these vectors. In contrast, CAT activity expressed from a vector containing the TRE DR + 4 was decreased by about 50% by T 3. Thus, TREp and TRE DR + 4 gave distinct responses. These data demonstrate that TR physiologically expressed in thyroid cells can act as transcriptional regulators in a T 3-dependent manner. This finding directly substantiates the concept of autocrine regulatory actions of thyroid hormones.

Ca2+-Dependent and Ca2+-Independent Regulation of the Thyroid Epithelial Junction Complex by Protein Kinases

The integrity of epithelial cell junctions is controlled by E-cadherin-mediated (Ca2+-dependent) cell–cell adhesion. In thyroid follicular cells the dissociation of junctions induced by transfer to low Ca2+medium (Ca2+switch) is prevented by thyrotropin acting via cyclic AMP/protein kinase A (cAMP/PKA) (Nilssonet al., Eur. J. Cell Biol.56, 308–318, 1991). In MDCK kidney epithelial cells protein kinase inhibitors elicit a similar response which, however, is cadherin-independent (Citi,J. Cell Biol.117, 169–178, 1992; Citiet al., J. Cell Sci.107, 683–692, 1994). As such inhibitors also may interfere with PKA, we examined in a single cell type, filter-cultured pig thyrocytes, the effects and possible interactions of the cAMP/PKA agonist forskolin (or thyrotropin) and the kinase inhibitor H-7 in Ca2+switch experiments. We found that the epithelial barrier dysfunction, comprising loss of transepithelial resistance, increased transepithelial flux of [3H]inulin and redistribution of junction proteins (cadherin and ZO-1), which follows Ca2+removal were inhibited by TSH, forskolin, and H-7. All agents were also able to induce recovery of resistance in low Ca2+. The maximal recovery effects of forskolin and H-7 were additive when given simultaneous with Ca2+chelator. In contrast, forskolin-induced recovery initiated 10 min after Ca2+removal was antagonized by H-7. The protection of junctions by forskolin in low Ca2+was rapidly abolished by light trypsinization (0.001%), whereas the same concentration of trypsin had little or no effect on the corresponding action of H-7 or staurosporine, another potent kinase inhibitor. In H-7-treated cells kept in low Ca2+, trypsin caused redistribution of ZO-1 from the plasma membrane to the cytoplasm while the transepithelial resistance remained high. Taken together, the data indicate that TSH via cAMP/PKA and the protein kinase inhibitor H-7 reinforce the thyroid epithelial barrier under low Ca2+conditions by distinct although interacting mechanisms. The high sensitivity to proteolysis in the absence of Ca2+suggests that the cAMP-regulated mechanism is cadherin-dependent. H-7 promotes or inhibits the cAMP/PKA-mediated recovery of transepithelial resistance depending on the duration of the preceding low Ca2+period. The trypsin-induced displacement of ZO-1 in H-7-treated cells in low Ca2+suggests that the localization of ZO-1 to the tight junction is not necessary for the maintenance of junctional tightness.

Effect of P1-purinergic agonist on thyrotropin stimulation of H2O2 generation in FRTL-5 and porcine thyroid cells

Our previous studies have shown that the generation of H2O2 in FRTL-5 thyroid cells is regulated via both the adenylate cyclase/cyclic adenosine monophosphate (cAMP) and Ca2+/phosphatidylinositol pathway: thyrotropin (TSH) stimulates H2O2 generation through both pathways, via the former at a low concentration and via the latter at a high concentration. In porcine thyrocytes in primary culture H2O2 generation is stimulated only via the Ca2+/phosphatidylinositol route. In the present study we explored the effect of a P1-purinergic agonist (phenylisopropyladenosine, PIA) on stimulations induced by TSH and by adenosine triphosphate (ATP), an activator of the Ca2+/phosphatidylinositol cascade via the P2-purinergic receptor. In FRTL-5 cells, PIA potentiated H2O2 generation stimulated by TSH at 10 U/l (but not at 1 U/l, Ca2+ mobilization induced by TSH and Ca2+ mobilization induced by ATP at 1 mumol/l (but not 10 mumol/l). Phenylisopropyladenosine strongly inhibited TSH-induced cAMP accumulation in FRTL-5 cells. In pig thyrocytes, PIA had no effect on H2O2 generation stimulated by TSH or ATP and no effect on ATP-stimulated Ca2+ mobilization. Also, PIA did not inhibit TSH-stimulated cAMP accumulation in pig thyrocytes, and by itself had no effect on H2O2 generation or Ca2+ mobilization. Thus, in FRTL-5 cells, but not in porcine thyrocytes, PIA modulates TSH-stimulated H2O2 generation by enhancing the Ca2+/phosphatidylinositol route and inhibiting the adenylate cyclase/cAMP route of the TSH signal. The net result of this modulation apparently depends on the balance between inhibition of the cAMP route and enhancement of the Ca2+ route. This may explain the lack of potentiation observed by 1 U/l TSH.

A 64 kDa antigen/glutamic acid decarboxylase (GAD) in fetal pig pro-islets: Co-precipitation with a 38 kDa protein and recognition by T cells in humans at risk for insulin-dependent diabetes

The development of insulin-dependent diabetes mellitus (IDDM) is associated with circulating antibodies to a pancreatic islet protein of MW 64,000 (64 kDa), reported to be glutamic acid decarboxylase (GAD). To investigate the antigenic properties of the 64 kDa antigen/GAD in IDDM we employed fetal pig pro-islets, a convenient source of islet antigens and an alternative to adult human islets for transplantation. Pro-islets contained a 64 kDa protein precipitated by antibodies in the sera of 9 14 (64%) at-risk IDDM, 12 33 (36%) recent-onset IDDM and 4 12 (33%) established IDDM patients and in 1 18 (5%) healthy control subjects. In addition, a 38 kDa protein was co-precipitated with the 64 kDa protein by 6 14 (43%) at-risk IDDM, 5 33 (12%) recent-onset IDDM, 1 12 (8%) established IDDM patient sera and 1 18 (5%) control subject serum. Both 64 kDa and 38 kDa antigens were specific to pro-islets; neither was detected in fetal pig thyrocytes, hepatocytes or splenocytes. The majority of the 64 kDa protein was co-precipitated with GAD enzymatic activity from pro-islets by either IDDM sera or a sheep anti-GAD serum. Previously, we showed that peripheral blood mononuclear cells (PBMC) from over half the subjects defined as being at risk for IDDM proliferate in response to fetal pig pro-islets. Proliferative responses of PBMC from pre-diabetic subjects to a crude extract of pro-islets were therefore measured before and after depletion of GAD by adsorption of the extract against GAD-1 monoclonal antibody. In 5 10 at-risk subjects, T cell stimulation indices were greater than the control mean+2 SD and decreased in four by > 50% after depletion of GAD. In summary, a 64 kDa protein with the properties of GAD is present in fetal pig pro-islets and is recognized by both antibodies and T cells in a significant proportion of subjects at risk for early IDDM. Some subjects with anti-64 kDa antibodies also have antibodies that co-precipitate a 38 kDa pro-islet protein. Prospective studies of T cell reactivity in at-risk IDDM subjects are required to delineate the role of GAD and other candidate autoantigens in the initiation and progression of β cell destruction.

Glycosyl phosphatidylinositol in thyroid: cell signalling or protein anchor?

During the last 10 years, attention has been focused on the stimulation by various agonists of the hydrolysis of phosphatidylinositol bis-phosphate into the second messengers inositol tris phosphate and diacylglycerol. Two other aspects of the metabolism of phosphoinositides were therefore not paid sufficient attention. The first one was the release by insulin of a glycosyl inositolphosphate from a glycosyl phosphatidylinositol, the hydrosoluble product being able to reproduce some of the hormone effects; the second was the discovery that several membrane proteins were anchored via a glycosyl phosphatidylinositol. For over 20 years, we have been interested in the effect of thyreostimulin (TSH) on the turnover of phosphatidylinositol in pig thyrocyte. As this effect did not seem to result from the hydrolysis of phosphatidylinositol bis-phosphate we explored another possibility, the synthesis of glycosyl inositol-phosphate. We have shown that, in cultured pig thyrocytes, TSH stimulates the release of the polar head of a glycosyl phosphatidylinositol. This soluble glycosyl inositol-phosphate which acts as insulin on adipocyte, modulates the cAMP accumulation and iodine metabolism in thyrocytes and could be held responsible for the cAMP independent effects of TSH. However, we do not yet know if there is a link between the glycosyl phosphatidylinositol sensitive to TSH and the anchor membrane protein. To date, the amount of 2 of these proteins: NAD glyco-hydrolase in thyroid cell membranes and heparan sulfate proteoglycan have been shown to be increased by TSH treatment of thyroid cells.