Regulation of heat shock protein 72 kDa and 90 kDa in human breast cancer MDA-MB-231 cells.

It has been shown that expression of HSPs can negatively regulate the effectiveness of cytotoxic drugs. In this study, we conducted experiments to study the regulation of expression of heat shock proteins (HSPs) in human breast cancer MDA-MB-231 cells. Using [35S]methionine incorporation and Western immunoblots, we established that heat shock increased production of HSP-72 and -90. Cells exposed to 44 degrees C for 20 min displayed increased expression of HSP-72 and -90, that reached a maximum 3-7 h later and returned to baseline levels within 24 h. The synthesis of both HSP-72 and -90 was attenuated when cells were exposed to heat shock in medium devoid of Ca2+ or pretreated with the calcium chelator BAPTA for 30 min prior to heat shock. Similarly, synthesis of HSP-72 and -90 was inhibited when cells were treated with the protein kinase A inhibitor, H89. These data indicate that Ca2+ and PKA are involved in the regulation of HSP-72 and -90 protein synthesis. Levels of HSP-72 mRNA in cells exposed to heat shock increased, suggesting that the heat-induced increase in HSP-72 occurs at the transcriptional level. Also, heat shock caused phosphorylation and translocation from the cytosol to the nucleus of heat shock factor 1 (HSF 1), a transcription factor for heat shock protein synthesis. Removal of external Ca2+ or treatment with a PKA inhibitor prevented the phosphorylation and the translocation of HSF 1. Cells overexpressing HSP-72 and -90 induced by exposure to a sublethal temperature displayed cytoprotection from thermal injury. Removal of external Ca2+ and treatment with BAPTA or H89 prior to exposure to sublethal heat shock that reduced the amount of HSP-72 and -90 production still protected cells from subsequent thermal injury. The intracellular free calcium concentration ([Ca2+]i) in resting fura-2-loaded MDA-MB-231 cells was 175+/- nM. Heat shock increased [Ca2+]i in a time-and temperature-dependent manner. Exposure of cells to 44 degrees C for 20 min increased [Ca2+]i by 234+/-13%, which subsequently returned to baseline levels within 30 min. Removal of external Ca2+ eliminated the increase, indicating that the increase in [Ca2+]i was due to Ca2+ influx. Pretreatment of the cells with H89 but not GF-109203X for 30 min led to an attenuation of the increase in [Ca2+]i by a subsequent heat shock. The results suggest that HSP-72 and -90 are regulated by [Ca2+]i and PKA activity in MDA-MB-231 cells. Kiang JG, Gist ID, Tsokos GC: Regulation of Heat Shock Protein 72 kDa and 90 kDa in Human Breast Cancer MDA-MB-231 Cells.

Biochemical requirements for the expression of heat shock protein 72 kda in human breast cancer MCF-7 cells.

Heat shock alters the susceptibility of tumor cells to chemotherapeutic agents. Cultured breast cancer MCF-7 and MDA-MB-231 cells that express high levels of heat shock protein 70 and 27 kDa are resistant to treatment with certain anticancer drugs. These findings indicate that expression of HSPs can negatively regulate the effectiveness of cytotoxic drugs. We conducted experiments to study the regulation of expression of heat shock proteins (HSPs) in human breast cancer MCF-7 cells exposed to heat shock by intracellular free Ca2+ and protein kinase C. Cells exposed to 44 degrees C for 20 min displayed increased expression of HSP-72 and GRP-94, that reached a maximum 4-5 h later and returned to baseline levels within 24 h. Levels of HSP-72 mRNA in cells exposed to heat shock increased, suggesting that the heat-induced increase in HSP-72 occurs at the transcriptional level. The synthesis of HSP-72 but not GRP-94 was inhibited when cells were exposed to heat shock in medium devoid of Ca2+ and attenuated by more than 50% when cells were pretreated with the calcium chelator BAPTA for 30 min prior to heat shock. HSP-72 synthesis was enhanced when cells were treated with the protein kinase C inhibitor, GF-109203X. These data indicate that Ca2+ and PKC are involved in regulation of HSP-72 synthesis. However, removal of external Ca2+ and treatment with BAPTA, GF-109203X, or exposure to sublethal heat shock protected cells from subsequent thermal injury. The intracellular free calcium concentration ([Ca2+]i) in resting fura-2-loaded MCF-7 cells was 156 +/- 16 nM (n = 29). Heat shock increased [Ca2+]i in a time- and temperature-dependent manner. Exposure of cells to 44 degrees C for 20 min increased [Ca2+]i by 234 +/- 13%, which subsequently returned to baseline levels within 120 min. Removal of external Ca2+ eliminated the increase, indicating that the increase in [Ca2+]i was due to Ca2+ influx. Pretreatment of the cells with BAPTA or GF-109203X for 30 min or a sublethal heat shock to allow HSP-72 overexpression led to an attenuation of the increase in [Ca2+]i by a subsequent heat shock. The results suggest that HSP-72 but not GRP-94 is regulated by [Ca2+]i and PKC activity. The cytoprotection produced by chelation of Ca2+, GF-109203X, or HSP-72 overexpression is probably due to their ability to attenuate the [Ca2+]i response to heating.

Characterization of distinct heat shock- and thapsigargin-induced cytoprotective proteins in FRTL-5 thyroid cells.

Heat shock induces the expression of proteins with molecular weights of 70-72 kd and 90 kd, whereas thapsigargin induces the expression of a glucose-regulated protein 78 kd (GRP-78) in certain cells. In this study we examined the induction and cytoprotective effects of heat shock- and thapsigargin-induced proteins in FRTL-5 rat thyroid cells. New protein synthesis was assessed in [35S]methionine-labeled cells and quantitated densitometrically. The expression of specific stress proteins was identified using Western blots, whereas cytoprotection provided by these proteins was evaluated by trypan blue exclusion. Exposure to heat shock (45 degrees C, 15 minutes) induced the expression of proteins with molecular weights at the range of low 70 kD and low 90 kD that peaked between 2-6 hours and returned to baseline within 24 hours. Treatment of cells with thapsigargin (200 nM, 15 minutes) induced the expression of different molecular weight proteins, most likely GRP-78 and -94, that peaked at 4-6 hours and lasted for 24 hours. Neither the removal of growth factors (thyroid-stimulating hormone and insulin) for 5 days nor the elimination of extracellular Ca2+ with EGTA or clamping of the intracellular Ca2+ with BAPTA for 15 minutes affected expression of the heat shock- and the thapsigargin-induced stress proteins. In contrast, protein kinase C inhibitors H7 and GF109203X abolished the expression of all three groups of stress proteins. Both heat shock- and thapsigargin-inuced proteins completely protected cells from subsequent thermal injury (47 degrees C, 35 minutes). The induction of cytoprotective proteins by heat shock and thapsigargin requires the presence of protein kinase C but is Ca(2+)- and growth factor-independent.

Crosslinking of Fas/CD95 suppresses the CD3-mediated signaling events in Jurkat T cells by inhibiting the association of the T-cell receptor zeta chain with src-protein tyrosine kinases and ZAP70.

Crosslinking of Fas (APO-1/CD95) on the surface of T cells initiates a biochemical cascade leading to programmed cell death. We have previously shown that crosslinking of Fas with an apoptosis-inducing IgM anti-Fas mAb results in suppression of the CD3-initiated cell signaling including Ca2+ mobilization and protein tyrosine phosphorylation. We conducted experiments to decipher the mechanisms whereby the cross talk between the Fas- and CD3 signaling pathways occur. We used lysates from Jurkat T and examined the composition of the TCR zeta chain-precipitated immune complexes using immunoblots. While crosslinking of Fas affected the association of p59fyn and p56lck tyrosine kinases with the TCR zeta chain to a limited degree, it dramatically inhibited the association of the protein tyrosine kinase ZAP70 with the zeta chain. In cells that were preincubated with an apoptosis-inducing anti-Fas mAb, the binding of the protein tyrosine phosphatases SHP-1 to the TCR zeta chain was increased. These experiments indicate that crosslinking of Fas interferes with early T cell signaling events by promoting the recruitment of SHP-1 and decreasing the association of protein tyrosine kinases with TCR zeta chain. Therefore, crosslinking of Fas antigen may regulate the antigen-induced T cell response and play an active role in the T cell anergy.

Cytoprotection and regulation of heat shock proteins induced by heat shock in human breast cancer T47-D cells: role of [Ca2+]i and protein kinases.

Overexpression of heat shock protein 70 kDa alters the susceptibility of tumor cells to chemotherapeutic agents. We conducted experiments to study the regulation of expression of heat shock proteins (HSPs) in heat shock-treated T47-D cells, a human breast cancer cell line that expresses estrogen receptors. Cells exposed to heat shock at 44 degreesC displayed increased expression of heat shock protein 72 kDa (HSP-72), glucose-regulated protein 78 kDa (GRP-78), and GRP-94 in a time-dependent manner, as shown by [35S]methionine incorporation and Western blotting experiments. The maximal rate of synthesis occurred between 2 and 4 h after heat shock. Removal of external Ca2+ inhibited the synthesis of the heat shock-induced GRP-78 but not of HSP-72 and GRP-94, whereas treatment of cells with BAPTA (a Ca2+ chelator) inhibited HSP-72 and GRP-78. Treatment with H89 (a protein kinase A inhibitor) blocked the heat shock-induced GRP-78 synthesis, whereas GF-109203X (a protein kinase C inhibitor) attenuated the heat shock-induced HSP-72 synthesis and completely blocked synthesis of GRP-78 but not of GRP-94. These results indicate that protein kinase C is involved in regulation of the heat shock-induced synthesis of HSP-72, whereas PKA and PKC are involved in the regulation of GRP-78 synthesis. Cells overexpressing HSP-72 and GRPs after heat shock displayed resistance against lethal temperature (47 degreesC for 50 min) -induced death, which was diminished after removal of external Ca2+ and treatment with GF-109203X. Heat shock increased intracellular free Ca2+ concentration ([Ca2+]i) in a temperature- and heating duration-dependent fashion, and the increase was inhibited in the absence of external [Ca2+]i and significantly reduced by pretreatment with H89 and GF-109203X. The results suggest that different pathways are involved in the induction of synthesis of HSP-72, GRP-78, and GRP-94 by heat shock. It is highly likely that only HSP-72 and GRP-78 are involved in the process of cytoprotection from the thermal injury.

Corticotropin-releasing factor induces phosphorylation of phospholipase C-gamma at tyrosine residues via its receptor 2beta in human epidermoid A-431 cells.

This laboratory previously reported that corticotropin-releasing factor (CRF) increased intracellular free calcium concentrations, cellular cAMP, inositol 1,4,5-trisphosphate, protein kinase C activity, and protein phosphorylation in human A-431 cells. The increase was blocked by CRF receptor antagonist. In this study, we identified the type of CRF receptors present and investigated whether CRF induced tyrosine phosphorylation of phospholipase C-gamma via CRF receptors. Using novel primers in reverse transcriptase-polymerase chain reaction, we determined the CRF receptor type to be that of 2beta. The levels of the CRF receptor type 2beta were not altered in cells treated with activators of protein kinase C, Ca2+ ionophore, or cells overexpressing heat shock protein 70 kDa. Cells treated with CRF displayed increases in protein tyrosine phosphorylation approximately at 150 kDa as detected by immunoblotting using an antibody against phosphotyrosine. Immunoprecipitation with antibodies directed against phospholipase C-beta3, -gamma1, or -gamma2 isoforms (which have molecular weights around 150 kDa) followed by Western blotting using an anti-phosphotyrosine antibody showed that only phospholipase C-gamma1 and -gamma2 were phosphorylated. The increase in phospholipase C-gamma phosphorylation was concentration-dependent with an EC50 of 4.2+/-0.1 pM. The maximal phosphorylation by CRF at 1 nM occurred by 5 min. The CRF-induced phosphorylation was inhibited by the protein tyrosine kinase inhibitors genistein and herbimycin A, suggesting that CRF activates protein tyrosine kinases. Treatment of cells with CRF receptor antagonist, but not pertussis toxin, prior to treatment with CRF inhibited the CRF-induced phosphorylation, suggesting it is mediated by the CRF receptor type 2beta that is not coupled to pertussis toxin-sensitive G-proteins. Treatment with 1,2-bis(2iminophenoxy)ethane-N,N,N',N'-tetraacetic acid attenuated the phospholipase C-gamma phosphorylation. In summary, CRF induces phospholipase C-gamma phosphorylation at tyrosine residues, which depends on Ca2+ and is mediated by activation of protein tyrosine kinases via the CRF receptor type 2beta.

17 beta-estradiol-induced increases in glucose-regulated protein 78kD and 94kD protect human breast cancer T47-D cells from thermal injury.

Heat shock alters the susceptibility of tumor cells to chemotherapeutic agents. We conducted experiments to study the regulation of expression of heat shock proteins (HSP) in 17 beta-estradiol-treated T47-D cells, a human breast cancer cell line. Cells exposed to 17 beta-estradiol for 24-48 h displayed increased expression of glucose regulated protein 78kD (GRP-78) and 94kD (GRP-94), as shown by [35S]methionine incorporation and Western blotting experiments. The increase was time (5 h to 48 h)-dependent at 1 nM and 1 microM 17 beta-estradiol. Cells overexpressing GRP-78 and -94 after treatment with 17 beta-estradiol displayed resistance against heat shock (47 degrees C for 50 min)-induced death. Removal of external Ca2+ or treatment of cells with BAPTA (a Ca2+ chelator) did not alter the synthesis of GRP-78 and -94, suggesting that the 17 beta-estradiol effect on the synthesis of GRP-78 and -94 is Ca(2+)-independent. In addition, exposure of cells to 17 beta-estradiol up to 100 microM did not increase [Ca2+]i, which further supports the view that the estrogen-induced GRPs are not regulated by [Ca2+]i. Treatment with H89 (a protein kinase A inhibitor, 1 microM, 30 min) or GF-109203X (a protein kinase C inhibitor, 1 microM, 30 min) also did not change the GRP synthesis, indicating that protein kinase A and C are not involved in regulation of GRP synthesis.

Heat shock inhibits the hypoxia-induced effects on iodide uptake and signal transduction and enhances cell survival in rat thyroid FRTL-5 cells.

Chronic hypoxia inhibits rat thyroid function in vivo. To determine possible mechanisms, we studied the effect of hypoxia on iodide uptake, the involvement of second messengers, and cell membrane permeability in rat thyroid FRTL-5 cells. Since sublethal heat stress protects tissues from ischemia, we also determined effects of heat stress. The initial rate of iodide uptake in untreated cells was between 12.98 and 15.28 pmol/micrograms DNA/min. Hypoxia (5% O2) increased the rate of uptake in a time-dependent manner. Heating cells at 45 degrees C for 15 min (heat shock) prior to exposure to hypoxia for 3 days inhibited the increase in the initial rate of I-uptake. Using fura-2, we found that the resting [Ca2+]i in suspended FRTL-5 cells was 65 +/- 7 nM (n = 16). [Ca2+]i was not increased in cells exposed to hypoxia for 1 day, while a 3-day exposure increased [Ca2+]i by 43 +/- 4% (p < 0.05); no additional increase occurred after 7 days of exposure. When cells were heated prior to hypoxia exposure for 3 days, the hypoxia-induced increase in [Ca2+]i did not occur. Similar observations were found with inositol trisphosphates (InsP3). Exposure of cells to hypoxia for 3 days increased InsP3 from 0.08 +/- 0.02 (n = 5) to 0.32 +/- 0.04% total cpm (n = 5, p < 0.05), but sublethal heating of cells prior to hypoxia exposure prevented the increase. Three-day hypoxia increased PKC activity in the membrane fraction (from 67 +/- 7 to 86 +/- 4% of total activity, p < 0.05), and heat shock inhibited these changes also. Immunoblots showed that hypoxia treatment alone and heat shock plus hypoxia resulted in the translocation of PKC-alpha, -delta, -epsilon, and -zeta isoforms, whereas heat shock alone translocated only PKC-beta I, -beta II, and -zeta. Cell membrane integrity was assayed by trypan blue exclusion. Hypoxia alone for 3 days did not affect membrane permeability, but only 49 +/- 3% of cells excluded trypan blue when a 3-day hypoxia exposure was followed by a 6 h reoxygenation. Heat shock prior to hypoxia and reoxygenation protected cell membrane function. Heat shock also induced heat shock protein 70 kDa (HSP-70) synthesis at the transcriptional level. Results suggest that heat shock protects FRTL-5 cells from hypoxic injury, perhaps by inhibiting the initial rate of iodide uptake and second messengers. It is likely that HSP-70 plays an essential role in the process of protection.

Immunoglobulins from Graves' disease patients stimulate phospholipase A2 and C systems in FRTL-5 and human thyroid cells.

We have studied the effects of immunoglobulin G from Graves' disease patients on phospholipase A2 (PLA2) and C(PLC) systems in FRTL-5 and human thyroid cells. Immunoglobulin G (IgG) from Graves' disease patients stimulated arachidonic acid (AA) release in a time- and dose-dependent manner. In FRTL-5 thyroid cells, removal of external calcium had no significant effect on the IgG (20 micrograms/ml)-induced AA release in FRTL-5 thyroid cells. U-73122 (3 mumol/l), a PLC inhibitor, and quinacrine (100 mumol/l) but not U-26384 (5 mumol/l), PLA2 inhibitors, blocked the IgG-induced (20 micrograms/ml) AA release in FRTL-5 thyroid cells. Immunoglobulin G (100 micrograms/ml) also stimulated accumulation of inositol-1,4,5-triphosphate (IP3) in a time- and dose-dependent (20-300 micrograms/ml) manner in FRTL-5 cells. Immunoglobulin G from Graves' disease patients induced a significant increase of IP3 production (p = 0.01) compared to IgG from normal subjects. Removal of external calcium had no significant effect on the IgG-induced IP3 production. The PLC inhibitor U-73122 completely blocked IgG-induced IP3 production from FRTL-5 thyroid cells. Also, in human thyroid cells, IgG from Graves' disease patients induced a significant increase of AA release (p = 0.001) and IP3 production (p = 0.004) compared to the IgG from normal subjects. These data indicate that IgG from Graves' disease patients induced PLA2 activity that was PLC dependent, a pattern referred to as sequential activation. Our studies suggest that IgG from Graves' disease patients activates PLA2 and PLC systems in FRTL-5 and human thyroid cells. These signal transduction pathways could be involved in the pathogenesis of Graves' disease and future studies are warranted to investigate this area.

P2-purinergic stimulation of iodide efflux in FRTL-5 rat thyroid cells involves parallel activation of PLC and PLA2.

Extracellular ATP increases inositol phosphates, cytosolic Ca2+ concentration ([Ca2+]i), arachidonic acid (AA) release, and iodide efflux in FRTL-5 cells. To examine the sequence of events in P2-purinergic receptor activation by ATP, a phospholipase C (PLC) inhibitor (U-73122) and a phospholipase A2 (PLA2) inhibitor (U-26384), as well as 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'- tetraacetic acid (BAPTA) and downregulation of protein kinase C (PKC) were used. ATP increased inositol trisphosphate (IP3), [Ca2+]i, AA release, and 125I efflux dose dependently. U-73122 inhibited the IP3 and calcium increase but not AA; U-26384 prevented AA release but not the increase in calcium. Both agents inhibited iodide efflux. BAPTA prevented any ATP-induced increase in [Ca2+]i without affecting AA release or 125I efflux. PKC downregulation had no effect on ATP-stimulated AA release, but reduced 125I efflux. We conclude that ATP-induced iodide efflux involves parallel, not sequential, activation of PLC and PLA2. No increase in [Ca2+]i or PKC activity is required for PLA2 activation. In contrast, an increase in 125I efflux depends on PKC and PLA2 activities, but not an increase in [Ca2+]i.

U-73122, an aminosteroid phospholipase C antagonist, noncompetitively inhibits thyrotropin-releasing hormone effects in GH3 rat pituitary cells.

TRH increases cytosolic-free calcium ([Ca2+]i) by activating phospholipase C(PL-C), which induces phosphoinositol hydrolysis, leading to Ca2+ mobilization from inositol trisphosphate (IP3) sensitive stores, and by increasing Ca2+ influx. Increases in [Ca2+]i stimulate PRL secretion. We investigated the effects of U-73122, an aminosteroid inhibitor of PL-C dependent processes, on TRH-stimulated second messenger pathways and on PRL secretion in GH3 rat pituitary cells. [Ca2+]i was monitored by Indo-1 fluorescence, and IP3 and metabolites separated on ion exchange columns. In Ca(2+)-free buffer, [Ca2+]i was 96 +/- 6 nM and increased to 323 +/- 23 nM (P less than 0.001) after TRH (100 nM). U-73122 dose dependently inhibited the TRH effect (IC50 = 967 nM; complete inhibition at 3-5 microM). Subsequent addition of monensin (100 microM) increased [Ca2+]i from 107 +/- 4 to 142 +/- 4 nM (P < 0.001), confirming our previous findings of a non-TRH regulated Ca2+ pool in GH3 cells. Pretreatment (15 sec) with U-73122 partly inhibited the TRH effect on [Ca2+]i; complete suppression occurred with 70 sec of pretreatment. An inactive analog (U-73343) had no inhibitory effect at 5 microM. U-73122 acted noncompetitively, as the mean maximum velocity (expressed as percent increase in [Ca2+]i after TRH) was reduced from 225 to 91 while the Michaelis-Menten constant for TRH was unchanged (15.4 vs. 13.8 nM, n = 3). Of note, U-73122, at 3-5 microM, increased basal [Ca2+]i from 109 +/- 5 to 120 +/- 5 nM (P less than 0.001). In 1.3 mM Ca2+ buffer containing nifedipine (1 microM) and verapamil (50 microM), similar effects of U-73122 (5 microM) were observed on basal and TRH-stimulated [Ca2+]i. IP3, IP2, and IP1 increased to 241 +/- 12%, 148 +/- 23%, and 167 +/- 39% of control, 30 sec after TRH (100 nM); these responses were prevented by 1 microM U-73122. At 5 microM, U-73122 also significantly increased IP3 levels. TRH (100 nM) increased 4-h PRL secretion from 16.3 +/- 1.4 to 27.6 +/- 3.2 ng/well (P less than 0.05). U-73122 (5 microM) increased basal PRL secretion to 35.9 +/- 3.2 ng/well (P less than 0.05), but abolished the TRH effect. In contrast, U-73343 (with Ca2+ channel blockers) did not inhibit the TRH effect on PRL (control: 24.3 +/- 2.1; TRH: 51.0 +/- 6.3 ng/well).(ABSTRACT TRUNCATED AT 400 WORDS)

Na+-H+ antiport and monensin effects on cytosolic pH and iodide transport in FRTL-5 rat thyroid cells.

Na+-H+ exchange may proceed via an endogenous antiporter or by exposure to the Na+ ionophore monensin. We investigated the characteristics of Na+-H+ exchange induced by antiporter stimulation and by monensin in FRTL-5 rat thyroid cells. We also examined the effects of intracellular pH (pHi) changes on iodide uptake and efflux. pHi was determined using 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein. The resting pHi was 7.33 +/- 0.02 units; this level correlated directly with extracellular pH. In acid-loaded cells, Km for external Na+ activation of the antiporter was 7.1 mM and maximum velocity was 0.3801 delta pH units/min. Dimethylamiloride was 42 times more potent than amiloride in inhibiting sodium-dependent recovery in acidified cells. Metabolic inhibition reduced the initial alkalinization rate. Monensin increased pHi, and this response was dependent on extracellular Na+ and HCO3- but not on antiporter function. Low-dose monensin (1 microM) and 1 mM NH4Cl enhanced 125I uptake. High-dose monensin (100 microM), but not NH4Cl, reduced iodide uptake. Neither NH4Cl nor monensin altered 125I efflux. Thus FRTL-5 cells possess an amiloride-sensitive Na+-H+ exchanger, which is not essential for maintaining basal pHi but is affected by ATP depletion. Monensin also alkalinizes these cells but independently of the antiporter. Iodide uptake, but not efflux, is affected by changes in intracellular Na+ and H+ levels.

8-Diethylamino-octyl-3,4,5-trimethoxybenzoate, a calcium store blocker, increases calcium influx, inhibits alpha-1 adrenergic receptor calcium mobilization, and alters iodide transport in FRTL-5 rat thyroid cells.

8-Diethylamino-octyl-3,4,5-trimethoxybenzoate (TMB-8) is known to inhibit mobilization of calcium from intracellular stores but, more recently, other cellular effects have been described. In the present study, the effects of TMB-8 on cytosolic free calcium [Ca2+]i levels in FRTL-5 rat thyroid cells were determined using the fluorescent dye, Indo-1. TMB-8 increased [Ca2+]i in a dose-dependent manner, with a maximum rise from 120 +/- 7 nM to 229 +/- 16 nM (90 +/- 5% increase) at 5 x 10(-4) M. This effect was considerably reduced in Ca2+ free buffer, demonstrating a dependency upon extracellular calcium influx but not upon membrane potential and which did not involve the Na+/Ca2+ exchanger. In Ca2+ free buffer TMB-8, at a dose which did not affect [Ca2+]i, completely prevented norepinephrine (10(-5) M) from mobilizing intracellular Ca2+. To determine whether TMB-8 affected differentiated functions, iodide uptake and efflux studies were performed with 125I. TMB-8 (10(-4) M) inhibited iodide uptake by approximately 40% without affecting efflux. At 10(-3) M TMB-8, efflux was also enhanced. These studies demonstrate that TMB-8 has at least two effects on [Ca2+]i, promoting calcium influx and preventing alpha-1 adrenergic mobilization from intracellular stores. TMB-8 also has multiple effects on 125I transport, both inhibiting influx and increasing efflux. The results emphasize the importance of characterizing the behavior of this compound in any cell system before using it as a biological probe.