SmMAK16, the Schistosoma mansoni homologue of MAK16 from yeast, targets protein transport to the nucleolus.

The SmMAK16 gene from Schistosoma mansoni was cloned by chance when an adult worm cDNA library was probed with antiserum to affinity-purified S. mansoni GSH S-transferases. SmMAK16 encodes a hydrophilic protein of 259 amino acids with a molecular mass of 31 kDa. The protein shares 43% sequence identity and 66% similarity to the nuclear protein MAK16 of Saccharomyces cerevisiae that has been implicated both in cell cycle progression and biogenesis of 60S ribosomal subunits. Both proteins display a similar degree of sequence similar to the hypothetical protein CeMAK16 from Caenorhabditis elegans. These proteins share a number of apparent protein motifs, including two nuclear localization signals (NLS), multiple sites for phosphorylation by protein kinase CK2 and four conserved cysteine residues that resemble a zinc binding domain. SmMAK16 mRNA is more highly expressed in adult female worm than males. Recombinant SmMAK16 was phosphorylated by human protein kinase CK2. When chimeric constructs containing SmMAK16 fused the green fluorescent protein (GFP) were transiently transfected into COS-7s cells, the reporter was localized not in nuclei, but exclusively in nucleoli. The yeast and nematode homologues were likewise able to direct nucleolar accumulation of the fluorescent reporter. The high degree of sequence conservation together with the ability to direct nucleolar protein transport supports the hypothesis that MAK16 proteins play a key role in the biogenesis of 60S subunits.

Schistosoma japonicum GSH S-transferase Sj26 is not the molecular target of praziquantel action.

It has been suggested that Sj26, a Schistosoma japonicum GSH S-transferase, is the molecular target of the antischistosomal drug praziquantel (McTigue et al., 1995, J. Mol. Biol. 246, 21-27). We tested this hypothesis by asking two questions: (1) does praziquantel inhibit Sj26 activity with a variety of model substrates; and (2) does praziquantel prevent the binding to Sj26 of physiologically relevant nonsubstrate ligands? High concentrations of praziquantel (up to 500 microM) did not inhibit Sj26 activity using the model substrates 1-chloro-2,4-dinitrobenzene, 3,4-dichloronitrobenzene, or ethacrynic acid. Sj26 had no measurable activity with two higher molecular weight GSH S-transferase substrates: 5-androsten-3,17-dione and sulfobromophthalein. We also assessed the ability of praziquantel to prevent the inhibition of Sj26 by a series of S-alkyl-GSH conjugates. The half-maximal inhibitory concentrations of S-hexyl-GSH, S-octyl-GSH, and S-decyl-GSH (10, 10, and 5 microM, respectively) for Sj26 were not affected by up to 500 microM praziquantel. This suggests that praziquantel does not compete with GSH for Sj26 binding. In order to determine if praziquantel disrupts binding of nonsubstrate ligands to Sj26, we tested praziquantel for its ability to prevent the inhibition of Sj26 by both bilirubin and hematin. Praziquantel (100 or 500 microM) did not alter inhibition of Sj26 by 3 microM bilirubin, but partially protected Sj26 against inhibition by hematin (0.1 to 2.0 microM). Interestingly, in a similar reaction, 100 microM S-methyl-GSH protected Sj26 from inhibition equally as well as praziquantel. Bovine serum albumin (5 microM) completely protected against inhibition by 1 microM hematin. These results indicate that although praziquantel partially protects Sj26 from hematin inhibition, this protection is neither specific to praziquantel nor physiologically relevant. Our results do not support the hypothesis that the mechanism of praziquantel action involves competitive inhibition of Sj26 catalytic activity or blocking binding of nonsubstrate ligands. We can, therefore, find no evidence that Sj26 is the molecular target of the antischistosomal activity of praziquantel.

Identification of amino acids in the tau 2-region of the mouse glucocorticoid receptor that contribute to hormone binding and transcriptional activation.

The tau 2-region of steroid hormone receptors is a highly conserved region located at the extreme N-terminal end of the hormone-binding domain. A protein fragment encoding tau 2 has been shown to function as an independent transcriptional activation domain; however, because this region is essential for hormone binding, it has been difficult to determine whether the tau 2-region also contributes to the transactivation function of intact steroid receptors. In this study a series of amino acid substitutions were engineered at conserved positions in the tau 2-region of the mouse glucocorticoid receptor (mGR, amino acids 533-562) to map specific amino acid residues that contribute to the hormone-binding function, transcriptional activation, or both. Substitution of alanine or glycine for some amino acids (mutations E546G, P547A, and D555A) reduced or eliminated hormone binding, but the transactivation function of the intact GR and/or the minimum tau 2-fragment was unaffected for each of these mutants. Substitution of alanine for amino acid S561 reduced transactivation activity in the intact GR and the minimum tau 2-fragment but had no effect on hormone binding. The single mutation L550A and the double amino acid substitution L541G+L542G affected both hormone binding and transactivation. The fact that the S561A and L550A substitutions each caused a loss of transactivation activity in the minimum tau 2-fragment and the full-length GR indicated that the tau 2-region does contribute to the overall transactivation function of the full-length GR. Overall, the N-terminal portion of the tau 2-region (mGR 541-547) was primarily involved in hormone binding, whereas the C-terminal portion of the tau 2-region (mGR 548-561) was primarily involved in transactivation.

Genetic analysis of the N-terminal end of the glucocorticoid receptor hormone binding domain.

Four site-directed missense mutations were constructed at the N-terminal end of the mouse glucocorticoid receptor (GR) hormone binding domain. This small subdomain is highly conserved among the steroid hormone receptors and is within a larger subregion believed to be important for hormone binding, transcriptional activation, and hsp90 binding. The ability of mutant and wild type GR to activate a reporter gene in response to various concentrations of dexamethasone was examined in transiently transfected COS-7 cells. Mutant GR species V544G (valine-544 changes to glycine) and V549G activated the reporter gene to approximately the same extent as wild type GR, but required approx. 7 and 23 times greater hormone concentrations, respectively. In contrast, double mutant LL541/2GG (leucines changed to glycines) could not activate transcription even at 10 microM dexamethasone or deacylcortivazol, while E543A (glutamic acid to alanine) was functionally indistinguishable from wild type GR. GR mutants LL541/2GG and V549G had reduced abilities to bind covalently to affinity label dexamethasone 21-mesylate. The partially and fully functional mutant GR species had no deficiency in transcriptional transactivation activity in the presence of saturating concentrations of agonist.

Two point mutations in the hormone-binding domain of the mouse glucocorticoid receptor that dramatically reduce its function.

Mouse lymphoma cell line W7M320b, a mutant WEH17 line, requires higher than normal concentrations of glucocorticoid to elicit the hormone responses that are characteristic of this lineage. Complementary DNA clones representing the glucocorticoid receptor (GR) mRNA were derived from the mutant cells, and the sequences coding for the hormone-binding domain were substituted for the analogous wild-type sequences in a GR cDNA expression vector. The function of the resulting GR proteins was tested by transient expression in COS-7 cells along with a glucocorticoid-inducible reporter gene in the presence of varying concentrations of glucocorticoid. From these assays and DNA sequence analyses, two independent functionally significant point mutations in the GR hormone-binding domain were identified. A mutant GR protein containing the single amino acid substitution, Pro547 to Ala, was still functional as a transcriptional activator, but only at hormone concentrations 100 times higher than those required by the wild-type receptor. A second mutant GR protein with a Cys742 to Gly substitution was unstable and almost completely nonfunctional.