Xenoendocrine disrupters-tiered screening and testing: filling key data gaps.

The US Environmental Protection Agency (EPA) is developing a screening and testing program for endocrine disrupting chemicals (EDCs) to detect alterations of hypothalamic-pituitary-gonadal (HPG) function, estrogen (ER), androgen (AR) and thyroid hormone synthesis and AR and ER receptor-mediated effects in mammals and other animals. High priority chemicals would be evaluated in the Tier 1 Screening (T1S) battery and chemicals positive in T1S would then be tested (Tier 2). T1S includes in vitro ER and AR receptor binding and/or gene expression, an assessment of steroidogenesis and mammalian (rat) and nonmammalian in vivo assays (Table 1). In vivo, the uterotropic assay detects estrogens and antiestrogens, while steroidogenesis, antithyroid activity, (anti)estrogenicity and HPG function are assessed in a 'Pubertal Female Assay'. (Anti-) androgens are detected in the Hershberger Assay (weight of AR-dependent tissues in castrate-immature-male rats). Fish and amphibian assays also are being developed. The fathead minnow assay can identify EDCs displaying several mechanisms of concern, including AR and ER receptor agonists and antagonists and inhibitors of steroid hormone synthesis. An amphibian metamorphosis assay is being developed to detect thyroid-active substances. Several alternative mammalian in vivo assays have been proposed. Of these, a short-term pubertal male rat assay appears most promising. An in utero-lactational screening protocol also is being evaluated. For Tier 2, the numbers of endocrine sensitive endpoints and offspring (F1) examined in multigenerational tests need to be expanded for EDCs. Consideration should be given to tailoring T2, based on the results of T1S. Tier 1 and 2 also should examine relevant mixtures of EDCs. Toxicants that induce malformations in AR-dependent tissues produce cumulative effects even when two chemicals act via different mechanisms of action.

Description and evaluation of a short-term reproduction test with the fathead minnow (Pimephales promelas).

Due to the time and expense associated with full life-cycle testing, most current toxicity tests with fish do not explicitly consider reproductive output as an endpoint but, rather, focus on early life-stage survival and development. However, some classes of chemicals could adversely impact reproduction at concentrations below those that affect development. Further, estimates of the effects of toxic compounds on reproductive output can be critical to the ecological risk assessment process. In this manuscript, we describe a short-term reproduction test with the fathead minnow (Pimephales promelas) and evaluate the test using two model reproductive toxicants, methoxychlor (an estrogenic compound) and methyltestosterone (an androgenic chemical). The test is initiated with reproductively mature animals and is comprised of a pre-exposure phase of 14 to 21 d, followed by a chemical exposure of up to 21 d. During and at completion of the test, several endpoints related to reproductive fitness and endocrine function are assessed. Both chemicals evaluated in our study caused a significant decrease in fecundity of the fish at nominal concentrations of 5.0 micrograms/L (methoxychlor) and 0.2 mg/L (methyltestosterone). Methoxychlor decreased plasma concentrations of one or more steroids (testosterone, 11-ketotestosterone, beta-estradiol) in both sexes and caused a significant induction of plasma vitellogenin in males, a response consistent with activation of the estrogen receptor by the pesticide (or its metabolites). Methyltestosterone decreased plasma concentrations of sex steroids and adversely affected gonadal status (as evaluated by relative weight and histopathology) in both sexes. The androgenic nature of methyltestosterone was clearly expressed as masculinization of exposed females via formation of nuptial tubercles, structures normally present only in reproductively active males. The chemical also caused a significant induction of plasma vitellogenin in both males and females; this unexpected estrogenic response was most likely due to aromatization of the androgen to a form capable of binding to the estrogen receptor. These studies demonstrate the utility of this short-term assay for identifying chemicals that exert reproductive toxicity through alterations in endocrine systems controlled by estrogens and androgens.

Aspects of basic reproductive biology and endocrinology in the fathead minnow (Pimephales promelas).

The fathead minnow (Pimephales promelas) has been proposed as a model species for assessing the adverse effects of endocrine-disrupting chemicals (EDCs) on reproduction and development. The purpose of these studies was to develop baseline reproductive biology and endocrinology data for this species to support interpretation of tests with potential EDCs. Pairs of reproductively-active fathead minnows (n=70) were evaluated with respect to reproductive cyclicity in terms of spawning interval and fecundity. The mode and mean (+/-SE) spawning intervals for the fish in this study were 3.0 and 3.7+/-0.1 days, respectively. The mean number of eggs produced per spawn was 85+/-2.8. Animals were sacrificed at periodic intervals during the established spawning cycle and measurements made of gonadal condition (gonadosomatic index [GSI], histopathology) and plasma concentrations of vitellogenin and sex steroids (beta-estradiol, testosterone, 11-ketotestosterone). The GSI in females varied significantly as a function of spawning interval, with the largest values occurring day 2 post-spawn, just prior to the interval of maximum spawning activity. Plasma beta-estradiol concentrations in females also varied significantly relative to peak values in the GSI and spawning activity. Vitellogenin concentrations in the female, and male GSI and steroid concentrations did not vary significantly relative to position in the spawning cycle. Concentrations of beta-estradiol in females and 11-ketotestosterone in males were positively correlated with testosterone concentrations.

Nitrogen excretion and expression of carbamoyl-phosphate synthetase III activity and mRNA in extrahepatic tissues of largemouth bass (Micropterus salmoides).

Low levels of all of the enzymes required for urea synthesis via the urea cycle, including mitochondrial glutamine- and acetylglutamate-dependent carbamoyl-phosphate synthetase III (CPSase III) and cytosolic glutamine synthetase, are known to be present in liver of the teleost fish largemouth bass (Micropterus salmoides). The levels of these enzymes are higher than those in most other teleosts, but they are significantly lower than the levels present in liver of ureoosmotic elasmobranchs. The purpose of this study was to assess the physiological role of CPSase III in the context of urea synthesis in adult bass. The results showed that urea-N accounts for about 30% of the total nitrogen (ammonia-N plus urea-N) excreted under control conditions. The rate of urea-N excretion did not increase in response to exposure to 1 mM NH4Cl (3 days) or 0.25 mM NH4Cl (12 days) in the external water, except for a transient increase after a day or two of exposure. CPSase III activity in liver also did not increase in response to exposure to ammonia. Adult largemouth bass, while apparently ureogenic, are primarily ammonotelic and remain so even in the presence of relatively high concentrations of ammonia in the external environment. The total units of CPSase III activity in liver are not sufficient to account for the quantity of urea that is excreted. However, CPSase III and ornithine carbamoyltransferase (OCTase) activities were found to be present in intestinal tissue and, unexpectedly, in muscle tissue. The total units of CPSase III and OCTase in muscle, intestine, and liver appear to be sufficient to account for the observed rate of urea excretion. The sequence of CPSase III cDNA was determined, which permitted the use of ribonuclease protection assays to demonstrate the presence of CPSase III mRNA in these tissues.

Expression of carbamoyl-phosphate synthetase III mRNA during the early stages of development and in muscle of adult rainbow trout (Oncorhynchus mykiss).

It has been reported that the activities of the urea cycle-related enzymes ornithine carbamoyltransferase and carbamoyl-phosphate synthetase III (CPSase III) are induced during early life stages of ammonotelic rainbow trout (Oncorhynchus mykiss), suggesting that the urea cycle may play a physiological role in early development in teleost fish (Wright, P. A., Felskie, A., and Anderson, P. M. (1995) J. Exp. Biol. 198, 127-135). CPSase III cDNA prepared from embryo mRNA was sequenced, confirming the existence of the CPSase III gene in trout and its expression. The deduced amino acid sequence of the CPSase III is homologous to other CPSases. Supporting evidence for the expression of CPSase III activity in trout embryos was obtained by demonstrating expression of CPSase III mRNA as early as day 3 post-fertilization, reaching a maximum at 10-14 days, declining to a minimum at day 70, and then increasing to a relatively constant level from days 90 to 110 (relative to total RNA). Unexpectedly, in tissues of adult and fingerling trout, CPSase III mRNA was found to be present in muscle but not in other tissues, including liver. This finding was confirmed by assay of extracts, which showed CPSase III and ornithine carbamoyltransferase activity in muscle but not in other tissues. The pyrimidine nucleotide pathway-related CPSase II mRNA was expressed in all tissues.

Reaction of the N-terminal methionine residues in cyanase with diethylpyrocarbonate.

Cyanase is an inducible enzyme in Escherichia coli that catalyzes the reaction of cyanate with bicarbonate to give ammonia and carbon dioxide. The enzyme is a decamer of identical subunits (M(r) = 17,000). Previous studies have shown that modification of either the single cysteine residue or the single histidine residue in each subunit gives an active decameric derivative that dissociates reversibly to inactive dimer derivative, indicating that decameric structure is required for activity and that the SH and imidazole groups are not required for catalytic activity [Anderson, P. M., Korte, J. J., Holcomb, T. A., Cho, Y.-G., Son, C.-M., & Sung, Y.-C. (1994) J. Biol. Chem. 269, 15036-15045]. Here the effects of reaction of the reagent diethylpyrocarbonate (DEPC) with cyanase or mutant cyanases are reported. DEPC reacts stoichiometrically with the histidine residue and at one additional site in each subunit when the enzyme is in the inactive dimer form, preventing reactivation. DEPC reacts stoichiometrically (with the same result on reactivation) at only one site per subunit with the inactive dimer form of cyanase mutants in which the single histidine residue has been replaced by one of several different amino acids by site-directed mutagenesis; the site of the reaction was identified as the amino group of the N-terminal methionine. DEPC does not react with the histidine residue of the active decameric form of wild-type cyanase and does not affect activity of the active decameric form of wild-type or mutant cyanases. Reaction with the N-terminal amino group of methionine apparently prevents reactivation of the mutant enzymes by blocking association to decamer.(ABSTRACT TRUNCATED AT 250 WORDS)

Formation of intersubunit disulfide bonds and properties of the single histidine and cysteine residues in each subunit relative to the decameric structure of cyanase.

Reaction of the single cysteine residue in each subunit of cyanase with certain SH reagents gives an active decameric derivative that dissociates reversibly to an inactive dimer derivative (Anderson, P. M., Johnson, W. V., Korte, J. J., Xiong, X., Sung, Y.-c., and Fuchs, J. A. (1988) J. Biol. Chem. 263, 5674-5680). Reaction of mixed disulfide dimer derivatives of cyanase with dithiothreitol at 0 degree C results in formation of a disulfide bond between the subunits in the dimer. The disulfide dimer was inactive and did not associate to a decamer; the intersubunit disulfide bond could not be formed when the dimers were associated as a decamer. The two SH groups apparently are in close proximity to each other in the dissociated dimer but not when the dimer is associated to a decamer. Substitution of glycine for the cysteine residue or of tyrosine, asparagine, glycine, valine, or leucine for the single histidine residue in each subunit gave mutant enzymes that were active. However, H113N, H113Y, and C83G were unstable at low temperature and/or ionic strength, dissociating reversibly to an inactive dimer. Efficient reassociation required the presence of bicarbonate or cyanate analog. The results are consistent with a proposed single site per subunit model explaining apparent half-site binding of substrates and the requirement of decameric structure for activity.

Carbonic anhydrase in Escherichia coli. A product of the cyn operon.

The product of the cynT gene of the cyn operon in Escherichia coli has been identified as a carbonic anhydrase. The cyn operon also includes the gene cynS, encoding the enzyme cyanase. Cyanase catalyzes the reaction of cyanate with bicarbonate to give ammonia and carbon dioxide. The carbonic anhydrase was isolated from an Escherichia coli strain overexpressing the cynT gene and characterized. The purified enzyme was shown to contain 1 Zn2+/subunit (24 kDa) and was found to behave as an oligomer in solution; the presence of bicarbonate resulted in partial dissociation of the oligomeric enzyme. The kinetic properties of the enzyme are similar to those of carbonic anhydrases from other species, including inhibition by sulfonamides and cyanate. The amino acid sequence shows a high degree of identity with the sequences of two plant carbonic anhydrases. but not with animal and algal carbonic anhydrases. Since carbon dioxide formed in the bicarbonate-dependent decomposition of cyanate diffuses out of the cell faster than it would be hydrated to bicarbonate, the apparent function of the induced carbonic anhydrase is to catalyze hydration of carbon dioxide and thus prevent depletion of cellular bicarbonate.

Effect of dietary copper deficiency on the distribution of dopamine and norepinephrine in mice and rats.

Dietary copper deficiency was produced in Swiss albino mice and Sprague Dawley rats to determine the organ specificity of alterations in norepinephrine (NE) and dopamine (DA) concentrations and the relationship with organ copper levels. A 5-week dietary treatment was used, which started 1 week after birth for mice, initially via dams, and 3 weeks after birth for rats. Mice offspring (6 weeks of age) and rats (8 weeks of age) maintained on a copper-deficient (-Cu) treatment were compared with copper-adequate (+Cu) controls. Compared with +Cu animals, -Cu mice and rats were anemic and had low (<1% of +Cu) ceruloplasmin activities but normal body weights. The -Cu mice had organ copper concentrations ranging between 30% and 65% of +Cu values for eight organs studied, with the thymus being the least depleted. For -Cu rats, the range was 15% to 65%. Significant reductions in NE concentration were observed in the heart, pancreas, and spleen of -Cu mice. Elevated DA levels were observed in all organs except the brain. For -Cu rats, the NE level was lower in the heart and the DA level was higher in both the heart and spleen compared with +Cu rats. Dopamine elevation in the heart and spleen for both -Cu mice and rats was four- and fivefold higher, respectively. Adrenal catecholamine levels were only slightly changed by copper deficiency in mice or rats. Urinary levels of both NE and DA were higher in -Cu rats and mice. Plasma and heart tyrosine levels were not altered in -Cu mice. Elevated DA in -Cu rodents may be due to limiting dopamine-beta-monooxygenase. Higher urinary NE and lower organ NE may be due to a combination of decreased synthesis and enhanced turnover. The magnitude of decreased organ copper was not predictive of altered catecholamine pool size.

Reversible dissociation of active octamer of cyanase to inactive dimer promoted by alteration of the sulfhydryl group.

Cyanase is an inducible enzyme in Escherichia coli that catalyzes the reaction of cyanate with bicarbonate resulting in the decomposition of cyanate to ammonia and bicarbonate. In this study, the role of the single sulfhydryl group in each of the eight identical subunits of cyanase was investigated. Tetranitromethane, methyl methanethiosulfonate, N-ethylmaleimide, and Hg2+ all reacted with the sulfhydryl group to give derivatives which had reduced activities and which dissociated reversibly to inactive dimer. Association of inactive dimer to active octamer was facilitated by the presence of azide (cyanate analog) and bicarbonate, increased temperature and enzyme concentration, and presence of phosphate. Nitration of tyrosine residues by tetranitromethane occurred only in the absence of azide and bicarbonate, suggesting that at least some of the tyrosine residues become exposed when octamer dissociates to dimer. Site-directed mutagenesis was used to prepare a mutant enzyme in which serine was substituted for cysteine. The mutant enzyme was catalytically active and had properties very similar to native enzyme, except that it was less stable to treatment with urea and to high temperatures. These results establish that in native cyanase the sulfhydryl group per se is not required for catalytic activity, but it may play a role in stabilizing octameric structure, and that octameric structure is required for catalytic activity.

Dietary copper deficiency alters protein and lipid composition of murine lymphocyte plasma membranes.

Protein and lipid analyses were conducted on isolated erythrocyte and lymphocyte plasma membranes from 7-wk-old male C57BL copper-deficient and copper-supplemented mice to investigate mechanisms for the altered immunity that accompanies dietary copper deficiency. Beginning at parturition, dams were fed a diet low in copper (0.5 mg/kg) and the offspring were weaned to this diet. Half the dams and their respective offspring received supplemental copper (20 mg/L) in the drinking water (+Cu) and served as controls. Unsupplemented offspring (-Cu) had lower activity of cuproenzymes serum ceruloplasmin, spleen and thymus cytochrome-c oxidase and copper, zinc-superoxide dismutase. The -Cu mice exhibited anemia, splenomegaly and thymic atrophy. Based on the marker enzyme alkaline phosphodiesterase I (APDE-I), lymphocyte plasma membranes were enriched 7- to 10-fold for spleen and thymus, respectively, after discontinuous sucrose density centrifugation. The activity of APDE-I was higher in spleen and thymus samples from -Cu mice than from those of +Cu mice for both crude homogenates and purified plasma membranes. Proteins were fractionated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by silver staining. A yellow-appearing band, Mr 74,000, present in all splenic membrane samples from +Cu mice was not evident in the samples from -Cu mice. Fatty acid methyl esters (FAME) were quantified by gas chromatography. Compared to splenic membranes from +Cu mice, the samples from -Cu mice demonstrated significant changes in all FAME (lower 16:0, 18:0 and 20:3n-6 and higher 18:1n-9, 18:2n-6 and 20:4n-6), including a higher unsaturation index. FAME composition of erythrocyte ghosts from -Cu mice demonstrated similar changes.(ABSTRACT TRUNCATED AT 250 WORDS)

Interaction of mono- and dianions with cyanase: evidence for apparent half-site binding.

Cyanase is an inducible enzyme in Escherichia coli that catalyzes bicarbonate-dependent hydrolysis of cyanate. The dianions oxalate, oxalacetate, and malonate are slow-binding inhibitors of cyanase, and some monoanions such as azide and chloride also inhibit cyanase activity [Anderson, P. M., & Little, R. M. (1986) Biochemistry 25, 1621-1626]. The purpose of this study was to investigate the interaction of selected dianions and monoanions by kinetic and equilibrium dialysis binding studies in an effort to obtain information about the active site and catalytic mechanism. Measurement of the effectiveness of 30 different dianions as inhibitors of cyanase showed a significant degree of structural and/or isomeric specificity and considerable variation with respect to the slow-binding nature of the inhibition. Oxalate and oxalacetate both show extreme slow-binding inhibition at very low concentrations. Kinetic studies of the rate of inhibition of cyanase by oxalate showed that the reaction is pseudo first order with respect to oxalate concentration and the results are consistent with a pathway in which oxalate forms a complex with the enzyme in a rapid initial reversible step followed by a slow isomerization step leading to a complex with a very low dissociation constant. The rate of inhibition is significantly reduced by the presence of relatively low concentrations of either azide (analogue of cyanate) or bicarbonate. Equilibrium dialysis binding studies showed that the stoichiometry of binding at saturation for oxalate, malonate, chloride, and bicarbonate is about 0.5 mol of ligand bound/mol of subunit for each compound.(ABSTRACT TRUNCATED AT 250 WORDS)

Serum cholesterol levels are not elevated in young copper-deficient rats, mice or brindled mice.

Experiments were conducted with suckling male C57BL mice and Sprague-Dawley rats to investigate the relationship between copper deficiency and elevated serum cholesterol. Brindled mice, which have a genetic defect that affects copper distribution, were compared to their normal brothers. Dietary copper deficiency was produced in dams heterozygous for the brindled gene, in normal mouse dams and in rat dams. The subsequent male offspring were compared to those from copper-supplemented dams. Copper deficiency, as assessed by liver copper levels or ceruloplasmin activity, was demonstrated in 12-d-old rats, brindled mice, and in genotypically normal mice from dams fed the copper-deficient diet. However, serum cholesterol levels were not elevated in these "copper-deficient" rats or mice. In one experiment serum cholesterol levels of brindled mice were significantly lower than that of their littermate controls. An additional study was done with older mice. Their dams were fed a low copper diet from parturition throughout lactation, and the pups were fed the same copper-deficient diet for 4 wk after weaning. The 7-wk-old male copper-deficient mice had liver copper levels below 1 microgram/g, but no elevation in serum cholesterol was observed. The failure to demonstrate a rise in serum cholesterol in these perinatal models may be due in part to less severe hepatic copper deficiency because of neonatal copper reserves in liver.