B-subunit of phosphate-specific transporter from Mycobacterium tuberculosis is a thermostable ATPase.

The B-subunit of phosphate-specific transporter (PstB) is an ABC protein. pstB was polymerase chain reaction-amplified from Mycobacterium tuberculosis and overexpressed in Escherichia coli. The overexpressed protein was found to be in inclusion bodies. The protein was solubilized using 1.5% N-lauroylsarcosine and was purified by gel permeation chromatography. The molecular mass of the protein was approximately 31 kDa. The eluted protein showed ATP-binding ability and exhibited ATPase activity. Among different nucleotide triphosphates, ATP was found to be the preferred substrate for M. tuberculosis PstB-ATPase. The study of the kinetics of ATP hydrolysis yielded K(m) of approximately 72 microm and V(max) of approximately 0.12 micromol/min/mg of protein. Divalent cation like manganese was inhibitory to the ATPase activity. Magnesium or calcium, on the other hand, had no influence on the functionality of the enzyme. The classical ATPase inhibitors like sodium azide, sodium vanadate, and N-ethylmaleimide were without any effect but an ATP analogue, 5'-p-fluorosulfonylbenzoyl adenosine, inhibited the ATPase function of the recombinant protein with a K(i) of approximately 0.40 mm. Furthermore, there was hardly any ATP hydrolyzing ability of the PstB as a result of mutation of the conserved aspartic acid residue to lysine in the Walker motif B, confirming the recombinant protein is an ATPase. Interestingly, analysis of the recombinant PstB revealed that it is a thermostable ATPase; thus, our results highlight for the first time the presence of such an enzyme in any mesophilic bacteria.

Evidence that phosphate specific transporter is amplified in a fluoroquinolone resistant Mycobacterium smegmatis.

We reported in an earlier study that active efflux of drug has a predominant role in conferring resistance in a laboratory-generated ciprofloxacin-resistant mutant of Mycobacterium smegmatis. This mutant exhibited mRNA level overexpression, as well as chromosomal amplification, of the gene pstB, encoding the putative ATPase subunit of phosphate specific transport (Pst) system. We demonstrate here that this mutant shows enhanced phosphate uptake and that inactivation of pstB in the parental strain results in loss of high affinity phosphate uptake and hypersensitivity to fluoroquinolones. These findings suggest a novel role of the Pst system in active efflux, in addition to its involvement in phosphate transport.

Involvement of a natural transport system in the process of efflux-mediated drug resistance in Mycobacterium smegmatis.

The phosphate-specific transporter (Pst) in bacteria is a multi-subunit system which belongs to the ABC family of transporters. The gene forms part of an operon and it is involved in phosphate uptake in prokaryotes. Its import function is known to be operative only under conditions of phosphate starvation. However, we found overexpression of this transporter in a Mycobacterium smegmatis strain selected for ciprofloxacin resistance (CIPr) which was grown under conditions in which the phosphate-scavenging function of this operon was inoperative. In CIPr cells, active efflux of the drug plays a predominant role in conferring high levels of fluoroquinolone resistance. We therefore investigated the role of this transporter in the process of efflux-mediated drug resistance by inactivating the pst operon in the CIPr strain. Phenotypic characterization of the resulting strain, CIPrd, showed a striking reduction in the minimal inhibitory concentration (MIC) of ciprofloxacin and in the drug extrusion profile as well. Genotype analysis, on the other hand, revealed partial disruption of the pst operon in CIPrd as a consequence of transporter gene amplification. Furthermore, disruption of this operon in wild-type cells resulted in hypersensitivity to ciprofloxacin and other xenobiotics to which CIPr cells exhibited cross-resistance. Thus our results provide strong evidence that Pst is a natural membrane transport system that has the ability to promote drug efflux in addition to its phosphate-scavenging function in the CIPr strain.

Role of an ABC importer in mycobacterial drug resistance.

Phosphate specific transporter (Pst) in bacteria is involved in phosphate transport. Pst is a multisubunit system which belongs to the ABC family of transporters. The import function of this transporter is known to be operative at media phosphate concentrations below the millimolar range. However, we found amplification of this transporter in a laboratory generated ciprofloxacin resistant Mycobacterium smegmatis colony (CIPr) which was grown in a condition when phosphate scavenging function of this operon was inoperative. Our results therefore argue the role of this ABC importer in conferring high level of fluoroquinolone resistance in CIPr.

Synergistic activation of yeast-expressed rat androgen receptor by modulators of protein kinase-A.

We have employed a yeast (Saccharomyces cerevisiae) based rat androgen receptor expression system to examine the cross-talk between different signalling pathways. We report here the synergistic modulation of androgen regulated transcriptional activation of beta-galactosidase reporter activity by the activators of protein kinase-A, like forskolin and 8-bromo-cyclic AMP. A similar ligand-dependent enhancement of reporter activity compared to a DHT treated control has been noticed with okadaic acid, which is a potent inhibitor of protein phosphatase. The activation could be blocked by protein kinase-A/C inhibitor, H7. Forskolin treatment neither altered levels of receptor mRNA nor [3H]R1881 binding to the receptor. Although it promotes binding of receptor to an androgen response element, forskolin was unable to activate subsequent interaction with the transcription machinery in the absence of androgen. Additionally, the synergistic actions of these activators were independent of the degree of androgen response element occupancy. Anti-androgens, cyproterone acetate and flutamide, which failed to exhibit antagonistic behaviour with yeast expressed receptor, were able to antagonize only the forskolin mediated augmentation of reporter activity. Finally, analyses of mutants established the role of DNA and steroid binding domains of receptor for this synergism.

Activation of rat androgen receptor by androgenic ligands is unaffected by antiandrogens in Saccharomyces cerevisiae.

The E. coli lacZ has been utilized as a reporter to evaluate ligand-mediated activation of the rat androgen receptor (AR) in Saccharomyces cerevisiae strain YCR1. beta-galactosidase activity was androgen-specific and was found to be inducible approximately 260-fold by dihydrotestosterone (DHT), testosterone and R1881. None of the antiandrogens tested was able to antagonize the DHT-dependent induction of beta-galactosidase activity. In the gel retardation assay, exposure of the receptor to DHT in vitro led to the formation of a protein-DNA complex that was not detected in yeast extracts unexposed to hormone. However, activation of AR by a steroidal (cyproterone acetate) and a non-steroidal antiandrogen (flutamide) either alone or in combination with DHT also results in a similar migration pattern. Additionally, LEM1, the ABC transporter that selectively modulates the biological potency of steroids in yeast, although operative in YCR1, was not responsible for antiandrogen resistance. These results thus indicate the involvement of other non-receptor factor(s) in mediating the effect of antiandrogens in yeast.

Identification of an ABC transporter gene that exhibits mRNA level overexpression in fluoroquinolone-resistant Mycobacterium smegmatis.

We describe here the PCR amplification of a DNA fragment (mtp1) from Mycobacterium smegmatis using primers derived from consensus sequences of the ABC family of transporters. The fragment encodes amino acid sequences that exhibited significant homology with different ABC transporters. Amino acid sequence alignment of the full length gene with other transporters identified the ABC protein as the B-subunit of the phosphate specific transporter. Strikingly, a M. smegmatis colony which exhibited a high level of ciprofloxacin resistance showed mRNA level overexpression of mtp1. Thus this is the first report in any prokaryote indicating differential expression of an ABC transporter in a fluoroquinolone resistant colony.

Involvement of an efflux system in mediating high level of fluoroquinolone resistance in Mycobacterium smegmatis.

A wild type strain of Mycobacterium smegmatis mc2 155 was serially adapted to 64 fold of minimal inhibitory concentration of an antimycobacterial agent, ciprofloxacin. This clone (CIPr) exhibited cross resistance to ofloxacin and ethidium bromide. The rate of drug efflux was accelerated in CIPr compared to the wild type strain. Verapamil, a calcium channel blocker, enhanced the drug accumulation in CIPr by diminishing the efflux and thus reversed the resistant phenotype. Additionally, a missense mutation was detected in the quinolone resistance determining region of the DNA-gyrase A subunit of CIPr. Taken together, these results suggest that drug efflux plays a major role in conferring such a high level of resistance in CIPr, in addition to the mutation in the DNA-gyrase locus.

Modular structure of glucocorticoid receptor domains is not equivalent to functional independence. Stability and activity of the steroid binding domain are controlled by sequences in separate domains.

A long-standing conundrum of glucocorticoid receptors has been why the steroid binding domain is active in hybrid proteins but not in isolation. For this reason, the precise boundaries of the steroid binding domain have not been defined. These questions have now been systematically examined with a variety of receptor deletion constructs. Plasmids encoding amino acids 537-673 and 537-795 of the rat receptor did not yield stable proteins, while the fusion of receptor or non-receptor sequences upstream of 537-673 afforded stable proteins that did not bind steroid. Wild type steroid binding affinity could be obtained, however, when proteins such as beta-galactosidase or dihydrofolate reductase were fused upstream of receptor amino acids 537-795. Studies of a series of dhfr/receptor constructs with deletions at the amino- and carboxyl-terminal ends of the receptor sequence localized the boundaries of the steroid binding domain to 550-795. The absence of steroid binding upon deletion of sequences in the carboxyl-terminal half of this domain was consistent with improperly folded receptor sequences. This conclusion was supported by analyses of the proteolysis and thermal stability of the mutant receptors. Thus, three independent regions appear to be required for the generation of the steroid binding form of receptors: 1) a protein sequence upstream of the steroid binding domain, which conveys stability to the steroid binding domain, 2) sequences of the carboxyl-terminal amino acids (674-795), which are required for the correct folding of the steroid binding domain, and 3) amino-terminal sequences (550-673), which may be sufficient for steroid binding after the entire steroid binding domain is properly folded. These results establish that the steroid binding domain of glucocorticoid receptors is not independently functional and illustrate the importance of both protein stability and protein folding when constructing mutant proteins.

Metal oxyanion stabilization of the rat glucocorticoid receptor is independent of thiols.

The ability of sodium molybdate, both to stabilize the steroid binding activity of glucocorticoid receptors and to prevent the activation of receptor-steroid complexes to a DNA binding species, has long been thought to involve thiols. Two receptor thiols in particular, Cys-656 and Cys-661 of rat receptors, have been suspected. The requirements for the action of molybdate, as well as two other metal oxyanions (tungstate and vanadate) known to exert the same effects as molybdate, have now been examined with receptors in which these thiols, or a third cysteine in the steroid binding cavity (Cys-640), have been mutated to serine. No mutation prevented any metal oxyanion from either stabilizing steroid-free receptors or blocking the activation of complexes for binding to nonspecific or specific DNA sequences. Thus, Cys-640, Cys-656, and Cys-661 are not required for any of the effects of molybdate, tungstate, or vanadate with rat glucocorticoid receptors. Studies with hybrid receptors, and with a 16-kDa steroid binding core fragment containing only 3 cysteines at positions 640, 656, and 661, indicated that no cysteine of the rat receptor was needed to maintain responsiveness to molybdate. Even when all of the thiol groups in crude cytosol were blocked by reaction with excess methyl methanethiol-sulfonate, each metal oxyanion was still able to stabilize the steroid binding of receptors. These results argue that molybdate, tungstate, and vanadate each interact with the receptor or an associated nonreceptor protein(s) in a manner that does not require thiols. An indirect mechanism of molybdate action was evaluated in light of the recent report that the whole cell actions are mediated by increased levels of intracellular cGMP. Under cell-free conditions, however, the effects of molybdate could not be reproduced by cGMP derivatives. Evidence consistent with a direct effect was that molybdate, tungstate, or vanadate each modified the kinetics of proteolysis of wild type receptors at 0 degrees C by trypsin, presumably due to induced conformational changes of the receptor. This alteration of trypsin digestion constitutes yet another effect of metal oxyanions on the glucocorticoid receptor.

Differential effects of the reversible thiol-reactive agents arsenite and methyl methanethiosulfonate on steroid binding by the glucocorticoid receptor.

The hormone binding domain of the glucocorticoid receptor contains a unique vicinally spaced dithiol, and when it is bound by arsenite under conditions that are specific for reaction with vicinally spaced dithiols versus monothiols, steroid binding activity is eliminated [Simons, S. S., Jr., Chakraborti, P. K., & Cavanaugh, A. H. (1990) J. Biol. Chem. 265, 1938-1945]. The vicinally spaced dithiol lies in a region of the receptor that appears to be a contact site for hsp90, which is required for the high-affinity steroid binding conformation of the glucocorticoid receptor [Dalman, F. C., Scherrer, L. C., Taylor, L. P., Akil, H., & Pratt, W. B. (1991) J. Biol. Chem. 266, 3482-3490]. As part of a long-term project to develop a vicinal dithiol-specific agent that will permit studies of ligand-induced conformational changes in this region of the receptor, we have examined here the differential effects of two reversible thiol-reactive agents, arsenite and MMTS. At low concentration, arsenite inactivates the steroid binding activity of the unliganded receptor in a vicinal dithiol-specific manner, whereas dissociation of steroid from untransformed, transformed, or DNA-bound transformed receptors occurs only at concentrations typical of monothiol interactions. MMTS produces a unique bimodal effect on the steroid binding capacity of the unliganded receptor at pH 9 that is pH-dependent and becomes essentially unimodal at physiological pH. Whereas arsenite disrupts the dexamethasone-receptor complex more readily than the triamcinolone acetonide-receptor complex, MMTS has the opposite effect. During treatment for 1 h at 0 degree C, neither reagent causes dissociation of hsp90 from the receptor.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of cysteines 640, 656, and 661 in steroid binding to rat glucocorticoid receptors.

The involvement of a vicinally spaced dithiol group in steroid binding to the glucocorticoid receptor has been deduced from experiments with the thiol-specific reagent methyl methanethiolsulfonate and the vicinal dithiol-specific reagent sodium arsenite. The vicinally spaced dithiol appears to reside in the 16-kDa trypsin fragment of the receptor, which is thought to contain 3 cysteines (Cys-640, -656, and -661 of the rat receptor) and binds hormone with an approximately 23-fold lower affinity than does the intact 98-kDa receptor. We now report that the steroid binding specificity of preparations of this 16-kDa fragment and the intact receptor are virtually identical. This finding supports our designation of the 16-kDa fragment as a steroid-binding core domain and validates our continued use of this tryptic fragment in studies of steroid binding. To identify the cysteines which comprise the vicinally spaced dithiol group, and to examine further the role of cysteines in steroid binding, a total of five point mutant receptors were prepared: cysteine-to-serine for each suspected cysteine, cysteine-to-glycine for Cys-656, and the C656,661S double mutant. Unexpectedly, each receptor with a single point mutation still bound steroid. Even the double mutant (C656,661S) bound steroid with wild type affinity. These results suggest that none of these cysteines are directly required either for steroid binding to the glucocorticoid receptor or for heat shock protein 90 association with the receptor. However, the presence of Cys-656 was obligatory for covalent labeling of the receptor by [3H]dexamethasone 21-mesylate. Studies with preparations of the 98 and 16 kDa forms of these mutant receptors revealed both that Cys-656 and -661 comprise the vicinally spaced dithiols reacting with arsenite and that any two of the three thiols could form an intramolecular disulfide after treatment with low concentrations of methyl methanethiolsulfonate. These data, in conjunction with those from experiments on the effects of steric bulk on various receptor functions, support a model for the ligand binding cavity of the receptor that involves all three thiols in a flexible cleft but where thiol-steroid interactions are not essential for binding.

Creation of "super" glucocorticoid receptors by point mutations in the steroid binding domain.

Almost all modifications of the steroid binding domain of glucocorticoid receptors are known to cause a reduction or loss of steroid binding activity. Nonetheless, we now report that mutations of cysteine 656 of the rat receptor, which was previously suspected to be a crucial amino acid for the binding process, have produced "super" receptors. These receptors displayed an increased affinity for glucocorticoid steroids and a decreased relative affinity for cross-reacting steroids such as progesterone and aldosterone. The increased in vitro affinity of the super receptors was maintained in a whole cell bioassay. These results indicate that additional modifications of the glucocorticoid receptor, and probably the other steroid receptors, may further increase the binding affinity and/or specificity.

Association of heat shock protein 90 with the 16 kDa steroid binding core fragment of rat glucocorticoid receptors.

We have recently described a 16 kDa steroid binding core (Thr537-Arg673) of the rat glucocorticoid receptor [Simons et al. (1989) J. Biol. Chem. 264, 14493-14497]. Sedimentation analysis and size exclusion and anion exchange chromatography now suggest that other proteins are associated with the 16 kDa receptor, just as has been seen for the intact 98 kDa receptor. The 16 kDa fragment was also immunoprecipitable with anti-heat shock protein 90 (hsp90) antibody. These results argue that hsp90 binds to the 16 kDa core fragment and directly position the site of hsp90 association between Thr537 and Arg673 of the rat glucocorticoid receptor.

Programmed T lymphocyte death. Cell activation- and steroid-induced pathways are mutually antagonistic.

Both cellular activation signals and exposure to glucocorticoids such as dexamethasone (Dex) cause programmed cell death in T cell hybridomas. When cells were activated in the presence of Dex, however, the degree of killing that was achieved by either stimulus alone was markedly reduced. Dex-induced programmed cell death of normal T cell clones was also prevented by cellular activation. Cyclosporin A (CsA) completely blocked the activation-induced death of T cell hybridomas, but actually enhanced the killing caused by Dex. The addition of CsA to activated T cell hybridomas in the presence of Dex allowed killing to proceed, consistent with ability of CsA to block activation-induced nuclear gene transcription. A number of independent approaches were used to explore the effect of activation on the glucocorticoid signaling/effector pathway. First, RU-486, which binds the glucocorticoid receptor and is a potent competitive antagonist of Dex, did not inhibit activation-induced cell killing. Second, activation of T cell hybridomas did not cause the translocation of the glucocorticoid receptor from the cytoplasm to the nucleus, nor did it prevent the receptor translocation induced by treatment with Dex. Finally, T cell hybridomas were transfected with a plasmid containing the chloramphenicol acetyltransferase (CAT) gene under the control of two tandemly arranged glucocorticoid-responsive elements. Activation of these cells did not induce CAT activity, and did not inhibit the CAT activity induced by Dex. In fact, there was a paradoxical increase in CAT activity when cells were treated with both stimuli. We conclude that cellular activation does not directly utilize the glucocorticoid receptor nor the glucocorticoid pathway when inducing programmed cell death. Furthermore, the ability of activation to inhibit Dex-mediated killing is not due to interference with the classical glucocorticoid signaling pathway, up to and including the initiation of gene transcription. Alternative mechanisms of antagonism, as well as the possible relevance of this phenomenon to the positive selection of self-recognizing thymocytes, are discussed.

Localization of the vicinal dithiols involved in steroid binding to the rat glucocorticoid receptor.

Our previous studies with the thiol-specific reagent methyl methanethiolsulfonate (MMTS) and the vicinal dithiol-specific reagent sodium arsenite have established that 2 spatially close thiols (i.e. vicinal dithiols) are involved in steroid binding to the intact 98 K rat glucocorticoid receptor. These 2 thiols form an intramolecular disulfide after treatment with low concentrations of MMTS. One of these thiols was proposed to by Cys-656. In an effort to identify both thiols, we have examined the effects of MMTS and arsenite on proteolytic fragments of the receptor, which contain progressively fewer cysteines. MMTS and arsenite are now found to cause the same dithiothreitol-reversible inhibition of steroid binding and affinity labeling of both the 42 K chymotrypsin fragment and the 16 K steroid-binding core fragment of the receptor as was seen for the intact receptor. Characteristic responses include a bimodal inhibition curve for steroid binding after preincubation with MMTS and an inhibition of binding by very low concentrations of arsenite. Low concentrations of MMTS could block steroid binding by forming a disulfide bond between the receptor and a tightly associated, nonreceptor protein. However, no evidence for such cross-linking was observed when intact 98 K receptors, 42 K chymotrypsin fragments, or 16 K trypsin fragments were treated with various concentrations of MMTS, separated on nonreducing sodium dodecyl sulfate-polyacrylamide gels, and visualized by Western blotting with antiheat shock protein 90 or antireceptor antibodies. One of the antireceptor antibodies (aP1) that had been raised against the rat receptor sequence 440-795 was now found to recognize at least 1 epitope in the 16 K core fragment. We conclude that the vicinal dithiols involved in steroid binding are 2 of the 3 cysteines in the sequence of Thr537-Arg673.

Arsenite and cadmium(II) as probes of glucocorticoid receptor structure and function.

Low concentrations of arsenite, but not arsenate, and Cd2+ blocked steroid binding to the glucocorticoid receptors of HTC cells. Inhibition by arsenite was faster and occurred at lower concentrations than for Cd2+. Half-maximal inhibition of [3H]dexamethasone binding was seen after a 30-min preincubation with approximately 7 microM arsenite. The effect of arsenite and of Cd2+ appears to be mediated by a reaction with vicinal dithiols of the receptor as shown by (a) the reversal of arsenite inhibition by much lower concentrations of dithiothreitol (approximately 0.1 mM) than of beta-mercaptoethanol (approximately 10 mM); (b) the ability of both arsenite and Cd2+ to block [3H]dexamethasone 21-mesylate labeling of receptors but not of other thiol-containing proteins; and (c) the known selectivity of arsenite and of Cd2+ for reactions with vicinal dithiols. Arsenite forms a tight complex with these vicinal dithiols since the removal of loosely associated arsenite by gel exclusion chromatography did not reverse the inhibition of steroid binding. The effect of other ions on steroid binding was also examined. Half-maximal inhibition of binding occurred with approximately 5 microM selenite, whereas up to 300 microM Zn2+ was without effect. Much higher concentrations of arsenite were required for effects on unactivated and activated complexes. Arsenite slowly induced a loss of unactivated complexes but rapidly inhibited a portion of the DNA binding of activated complexes. Any effect on activation occurred at arsenite concentrations equal to or higher than those that inhibited DNA binding. In contrast, Cd2+ concentrations similar to those that block steroid binding caused a biphasic loss of unactivated complexes and a marginal loss of activated complexes. This is the first report of effects of arsenite on glucocorticoid receptors. These results confirm directly our earlier hypothesis that steroid binding to rat glucocorticoid receptors involves a vicinal dithiol (Miller, N. R., and Simons, S. S., Jr. (1988) J. Biol. Chem. 263, 15217-15225) and show that arsenite is a potent new reagent for probing receptor structure and function.

Steroid binding activity is retained in a 16-kDa fragment of the steroid binding domain of rat glucocorticoid receptors.

The steroid binding domain of the rat glucocorticoid receptor is considered as extending from amino acids 550 to 795. However, such a synthetic protein (i.e. amino acids 547-795; Mr approximately 31,000) has been reported to show very little affinity for the potent synthetic glucocorticoid dexamethasone. We now disclose that digestion of steroid-free rat glucocorticoid receptors with low concentrations of trypsin yields a single species, of Mr = 16,000, that is specifically labeled by dexamethasone 21-mesylate. This 16-kDa fragment retains high affinity binding for [3H]dexamethasone that is only approximately 23-fold lower than that seen with the intact 98-kDa receptor. Analysis of the protease digestion patterns obtained both with trypsin and with lysylendopeptidase C allowed us to deduce the proteolytic cleavage maps of the receptor with these enzymes. From these protease maps, the sequence of the 16-kDa fragment was identified as being threonine 537 to arginine 673. These results show that glucocorticoid receptor fragments smaller than 34 kDa do bind steroids and that the amino acids Thr537-Arg673 constitute a core sequence for ligand binding within the larger steroid binding domain. The much slower kinetics in generating the 16-kDa fragment from affinity-labeled receptors suggests that steroid binding causes a conformation change in the receptor near the cleavage sites.

Effect of acid environments on cortisol and cortisol receptor activity in Atlantic salmon,Salmo salar.

The cytosol and nuclear extract of gill tissue obtained from laboratory held Atlantic salmon,Salmo salar manifested saturable cortisol binding of high affinity and low capacity (cytosol: Ka = 0.198 ± 0.024 × 10(9)/M, Nmax = 116.8 ± 20.8 fmol/mg protein; nuclear extract: Ka = 0.823 ± 0.057 × 10(7)/M, Nmax = 1563 ± 330 fmol/mg protein; n = 4). The cytosol receptor activity displayed high steroid and tissue specificity and a single binding peak at 191,000 Da following gel permeation chromatography.Atlantic salmon exposed for 3 or 8 months to waters from the Medway River (pH about 5.1), the Westfield River (pH about 4.8) and calcium carbonate treated Westfield River (pH about 5.6) showed no gill cytosol receptor activity. Cortisol receptor activity in the gill nuclear extracts from fish in limed Westfield River water in December (3 months) was less than half the activity in the fish treated with Medway River water (p < 0.05) although the plasma cortisol values were not different. In May (8 months), the plasma cortisol of fish in limed water was almost twice that of the fish held in acid Westfield River water (p = 0.058).

Dynamics of cortisol receptor activity in the gills of the brook trout, Salvelinus fontinalis, during seawater adaptation.

Injection of cortisol into freshwater-adapted brook trout caused a rapid increase in plasma cortisol and a significant drop in plasma osmolality, thyroxine (T4), and chloride concentrations, but a nonsignificant drop in plasma triiodothyronine (T3). Concomitantly, cortisol cytosolic receptor activity decreased and cortisol nuclear extract receptor activity increased significantly. Transfer of brook trout into 30% seawater evoked a significant rise in plasma cortisol, osmotic, and chloride concentrations and a significant drop in plasma T4 and T3. Cortisol cytosol receptor activity rapidly dropped following entry into seawater, and cortisol nuclear extract receptor activity rose significantly in a manner similar to the effects of the injection of cortisol. Although there was a lack of correlation between the cytosol cortisol concentration and the cytosol receptor concentration, a significant and positive correlation occurred between the nuclear extract cortisol concentration and the nuclear extract cortisol receptor activity. This positive correlation may reflect an important role for the putative nuclear receptor. These results support the hypothesis that cortisol has an important role in the adaptation of brook trout to the marine environment.