Prolactin expression is induced in Jurkat T-cells by beta-catenin LEF-1, AP-1 and cAMP.

Prolactin (PRL) in humans is produced in the pituitary as well as in extra-pituitary sites. A proximal promoter that requires the Pit-1 transcription factor controls pituitary PRL expression, whereas a distal (upstream) promoter located at 5.8 kb upstream of the pituitary start site regulates extra-pituitary PRL synthesis. We have previously reported that cAMP regulates PRL transcription in Jurkat lymphocytes in part through a cAMP responsive element. Here we demonstrate that additional PRL regulatory elements corresponding to LEF-l and AP-1 transcription factor binding sites appear important for PRL expression, since factor binding by EMSA and reporter gene expression are reduced when these sites are deleted or mutated. Interestingly, over-expression of a constitutively active form of beta-catenin increases PRL expression of Jurkat cells. This effect occurs through both LEF-dependent and -independent pathways. Our studies identify the distal PRL promoter as a target for beta-catenin, and reveal novel pathways regulating extra-pituitary PRL expression.

A member of the heat shock protein 40 family, hlj1, binds to the carboxyl tail of the human mu opioid receptor.

A yeast two-hybrid screen, using the carboxyl tail of the human mu opioid receptor as bait and a human brain cDNA library as target, indicated that the carboxyl terminal portion of hlj1, a member of the human heat shock protein 40 family, interacts with the carboxyl tail of the human mu opioid receptor. To determine if direct in vitro binding occurs between these two proteins, we performed overlay experiments. Results from the overlay experiments showed that binding occurs between the His fusion protein of hlj1 and the GST fusion protein of the carboxyl tail of the human mu opioid receptor. In contrast, no binding with the His fusion protein of hlj1 occurred with GST alone or the GST fusion protein of the third cytoplasmic loop of the human mu opioid receptor. Results from co-immunoprecipitation studies, carried out in whole HEK cell lysates, confirmed in vivo binding between these two proteins. Immunofluorescent studies, using laser scanning confocal microscopy, showed significant co-localization between hlj1 and the human mu opioid receptor in the cell membrane. The function of this protein-protein interaction and its physiological relevance in animal and human brain is yet to be determined.

Identification of a neurorestrictive suppressor element (NRSE) in the human mu-opioid receptor gene.

Analysis of the DNA sequence of the human mu-opioid receptor gene (MOR) revealed that a region overlapping the start codon was substantially homologous to a DNA element named the neurorestrictive suppressor element (NRSE) or restrictive element 1 (RE-1). Transient transfection experiments in the L929 and HEK non-neural cell lines showed that expression of a MOR promoter/reporter gene construct was suppressed in non-neural cell lines by inclusion of this MOR NRSE. Expression from a thymidine kinase promoter was also suppressed when the MOR NRSE was inserted upstream or downstream of the reporter gene. The MOR NRSE did not suppress expression of the reporter gene in neural derived cell lines, IMR-32 and Neuro 2a. The transcription factor REST which binds NRSE thereby enacting the suppression of transcription, was encoded in a plasmid and co-transfected into the IMR-32 cells. The REST co-transfected neuronal derived (IMR-32) cells became sensitive to the MOR NRSE mediated suppression of reporter gene expression. Electrophoretic mobility shift experiments revealed that oligonucleotides containing the MOR NRSE were bound by a factor from nuclear extracts of non-neural cell lines, HeLa and Jurkat. This binding was specifically competed by oligonucleotides containing NRSE sequences previously shown to suppress transcription through REST. Thus an NRSE element overlapping the human MOR start codon suppresses gene expression in non-neural cell lines and may help direct neural tissue specific expression of MOR.

Tyrosine phosphorylation of the delta-opioid receptor. Evidence for its role in mitogen-activated protein kinase activation and receptor internalization*.

The internalization of G-protein-coupled receptors (GPCRs), including the delta opioid receptor (delta-OR), has been shown to involve the phosphorylation of serine and threonine residues. However, recent studies suggest that these residues may not be the only ones phosphorylated in response to prolonged opioid exposure. Tyrosines also appear important for delta-OR signalling, but it remains unclear whether they undergo phosphorylation. We examined whether the delta-OR, stably expressed in Chinese hamster ovary (CHO-K1) cells, was tyrosine-phosphorylated during prolonged agonist treatment. The epitope-tagged delta-OR was purified by immunoprecipitation, and the presence of phosphorylated tyrosines was detected using anti-phosphotyrosine antibodies. Tyrosine residues in the delta-OR were phosphorylated after exposure to the high-affinity agonist [d-Thr(2)]-Leu-enkephalin-Thr (DTLET) in a time- and concentration-dependent manner. Tyrosine phosphorylation of the delta-OR appeared to require the actions of a Src-like protein tyrosine kinase, since the Src inhibitor 4-amino-5-(4-methylphenyl)-7-(t-butyl)-pyrazolo-[3,4-d]-pyrimidine (PP1) attenuated this response. PP1 also attenuated the DTLET-mediated activation of mitogen-activated protein kinase, as well as rapid delta-OR internalization, but not receptor down-regulation. Finally, only opioid agonists that induce receptor internalization via the clathrin-dependent endosomal pathway stimulated significant tyrosine phosphorylation of the delta-OR protein. Evidence is presented that the delta-OR is tyrosine-phosphorylated, and we suggest how this may have an active role in opioid receptor signalling and regulation.

Mutation of tyrosine 318 (Y318F) in the delta-opioid receptor attenuates tyrosine phosphorylation, agonist-dependent receptor internalization, and mitogen-activated protein kinase activation.

Opioid receptors are known for their ability to activate diverse second messenger systems. Previously, we showed that selective delta-opioid agonists were able to induce the rapid tyrosine phosphorylation of delta-opioid receptors (delta-ORs) through Src. Src-dependent tyrosine phosphorylation of delta-ORs appears to be important for activation of the mitogen-activated protein kinase cascade and for receptor sequestration into clathrin-coated endosomes, as the Src antagonist, PP1, inhibited both. In an attempt to clarify the role of tyrosine phosphorylation in delta-OR signalling and regulation, we constructed a mutant receptor in which the tyrosine located in the conserved NPXXY motif of the C-terminus was replaced by a phenylalanine (Y318F-delta-OR). Mutation of Y318 resulted in a receptor that was comparable to the wild type in its expression level in HEK-293 cells and in its affinity for opioid ligands. Both receptors showed effective coupling to G proteins and were capable of inhibiting forskolin-stimulated cAMP accumulation with similar potencies. However, the mutant receptor was able to stimulate (35)S-GTPgammaS binding with a lower EC(50) than the wild type receptor. The stimulation of tyrosine phosphorylation in delta-ORs by [D-Thr(2)]-Leu-enkephalin-Thr (DTLET) was significantly less in cells expressing the Y318F-delta-OR than in cells expressing the wild type. In addition, both rapid receptor internalization and down-regulation were markedly attenuated in the mutant. Finally, the mutant receptor was unable to induce a robust activation of the MAPK pathway, suggesting that tyrosine phosphorylation of the delta-OR protein is important for this signalling pathway. These findings implicate tyrosine phosphorylation of Y318 in receptor signalling and agonist-mediated regulation.

The bovine mu-opioid receptor: cloning of cDNA and pharmacological characterization of the receptor expressed in mammalian cells.

The cDNA coding for the bovine mu-opioid receptor has been cloned and sequenced. Conserved sequences from murine delta-receptor cDNA were used as primers in polymerase chain reaction (PCR) to amplify cDNA, prepared by reverse transcription of bovine brain mRNA. This cDNA was used to probe a bovine brain library. The partial sequence obtained was extended to provide the full length clone by PCR. The cDNA has an open reading frame of 1203 base pairs (bp) with a 3'-untranslated region of 1900 bp and a 5'-untranslated region of 265 bp. The protein contains 401 amino acids and has 94% amino acid identity with the human and 91% with the rat mu-opioid receptor. It has the putative seven transmembrane domains, characteristic of G protein-coupled receptors and contains 5 potential N-linked glycosylation sites near the N-terminus. Several potential phosphorylation sites and a putative palmitoylation site are also present. The receptor was stably expressed in HEK293 cells. The binding profile was found to be that of a typical mu receptor, i. e., mu agonists and antagonists, but not delta and kappa ligands, bound with high affinity. Functional assays, namely, opioid stimulation of [35S]GTPgammaS binding and inhibition of forskolin-activated adenylyl cyclase, were also found to be highly specific for mu-opioid agonists. The receptor was downregulated by chronic exposure to mu agonists but not delta or kappa agonists. Evidence is presented indicating that the cloned receptor is the same as the bovine mu receptor previously purified to homogeneity in our laboratory. No evidence was found for genes for multiple mu-type opioid receptors.

Localization of promoter elements in the human mu-opioid receptor gene and regulation by DNA methylation.

The regulation of mu-opioid receptor gene expression was investigated using several molecular techniques. Genomic clones containing portions of the human mu-opioid receptor gene were sequenced. 5'-RACE analysis of human brain cDNA confirmed the presence of mRNAs up to -313 from the start codon. As was found for the mouse and rat genes, transcription apparently initiates in the absence of a discernable TATA box. To characterize promoter function, portions of the 5'-flanking region were linked to a reporter gene in transient transfection experiments. Two approximately 50 bp adjacent segments had potent, orientation specific promoter activity. More down-stream segments also had promoter activity. None of the 5'-flanking region constructs showed tissue specificity. The potential role of DNA methylation in preventing ectopic expression was investigated by surveying the methylation state of a CpG rich region straddling the start codon. A neural derived cell line (SH-SY5Y) that expresses the mu-opioid receptor lacked virtually any CpG methylation. In contrast, two neural derived cell lines that do not express the mu-opioid receptor were nearly totally methylated while non-neural cell lines had intermediate levels of CpG methylation. Additional transient transfection experiments revealed that CpG methylation of the 5'-flanking region suppressed reporter gene expression. These results indicate that CpG methylation plays an important role in regulating mu-opioid receptor expression in neural cells; however, no association was found with regulation of expression in non-neural cells.

Functional significance of cysteine residues in the delta opioid receptor studied by site-directed mutagenesis.

Previous work suggested that sulfhydryl groups and disulfide bridges have important functions in opioid binding to the delta opioid receptor. The question regarding which cysteines are essential for ligand binding was approached by replacement of cysteine residues in the cloned delta opioid receptor using site-directed mutagenesis. The wild-type and mutant receptors were expressed stably in Chinese hamster ovary cells. The two extracellular cysteine residues and the six located in transmembrane domains were mutated to serine or alanine, one at a time. Replacement of either of the extracellular cysteines produced a receptor devoid of delta agonist and antagonist binding activity. Immunofluorescence cytochemistry, performed with anti delta opioid receptor antibodies in washed cell monolayers in one of these mutants (Cys-Ser121), and immunoblots, performed on cell extracts, indicate that the receptor was expressed and seems to be associated with the cell membrane. The existence of an essential extracellular disulfide bridge, previously postulated by analogy to other G protein coupled receptors, is strongly supported by our results. Replacement of any one of the six transmembrane cysteines was virtually without effect on the ability of the receptor to bind delta agonists and antagonists. Since there is strong evidence that the transmembrane domains are involved in ligand binding, these results suggest that the cysteine residues, even those near or at the binding site, are not essential for receptor binding. Furthermore, these results support the idea that the striking effects of sulfhydryl reagents on ligand binding of opioid receptors are likely to be due to steric hindrance by the large moieties transferred to the sulfhydryl groups of cysteine residues by these reagents.

Expression of TAPA-1 in preimplantation mouse embryos.

TAPA-1 is a member of a new family of evolutionarily conserved transmembrane proteins which may be involved in regulation of cell growth and/or cell signalling. We have examined the temporal pattern of TAPA-1 RNA expression during mouse development. Using a sensitive reverse transcription/polymerase chain reaction assay, we show that TAPA-1 RNA is present in oocytes, fertilized eggs and cleavage stage embryos.

Structure and membrane topology of TAPA-1.

TAPA-1 (the target of an antiproliferative antibody) is a 26-kDa cell surface protein expressed on most human cell lines. TAPA-1 is a member of an evolutionarily related family of cell surface proteins all of which contain four transmembrane domains. A model is proposed for topology of TAPA-1 based on proteolysis studies in the in vitro translated protein embedded into microsomal membranes. This analysis predicts that the amino and the carboxyl termini of the molecule are cytoplasmic and that the two hydrophilic regions of the molecule are extracellular. The antigenic epitope of the human TAPA-1 is contained within a subregion of the second extracellular domain of the protein. This is the only region in the protein that has not been tightly conserved in mammalian evolution.

Genomic organization and chromosomal localization of the TAPA-1 gene.

TAPA-1 is a 26-kDa integral membrane protein expressed on many human cell types. Antibodies against TAPA-1 induce homotypic aggregation of cells and can inhibit their growth. The murine homologue of TAPA-1 was cloned from both cDNA and genomic DNA libraries. A very high level of homology was found between human and mouse TAPA-1. The 5' untranslated region of the TAPA-1 gene resembles housekeeping gene promoters with respect to G + C content and the presence of potential Sp1 binding sites. The chromosomal localization of human and murine TAPA-1 genes was determined by Southern blot experiments using DNA from somatic cell hybrids. The genes were found to be part of a conserved syntenic group in mouse chromosome 7 and the short arm of human chromosome 11. The organization of the TAPA-1 gene and the projection of the exon boundaries on the proposed protein structure are presented.

Diverse VH and VL genes are used to produce antibodies against a defined protein epitope.

mAb secreting hybridomas were produced from mice hyperimmune to the model Ag tobacco mosaic virus protein. Six mAb were selected for their ability to bind synthetic peptides corresponding to amino acid residues 103-112 and 97-107 of tobacco mosaic virus protein. These mAb were analyzed for their fine specificity by measuring binding to synthetic analogs of the decapeptide, and cDNA sequences encoding the mAb V regions were determined. These analyses revealed that a wide range of different V regions are capable of binding with the same decapeptide epitope, and that these antibody sequence differences generally coincided with different binding fine specificities. This diverse antibody response with specificity for the same epitope demonstrates both the breadth of potential of the immune system and the lack of exclusivity in specific protein:protein interactions.

Steroid induced exocytosis: the human sperm acrosome reaction.

By a combination of organic precipitation and high pressure liquid chromatography, human sperm acrosome reaction inducing activity has been purified from the fluid aspirated from preovulatory human ovarian follicles and identified as 4-pregnen-3,20-dione (progesterone) and 4-pregnen-17 alpha-ol-3,20-dione (17 alpha-hydroxyprogesterone). It is argued that progesterone is present at the site of fertilization of placental mammals in concentrations sufficient for activity, and hence provides a mechanism of inducing the acrosome reaction, an exocytotic event, in vivo.

Structural features of an antigen required for cellular interactions and for T cell activation in a MHC-restricted response.

The protein Ag, tobacco mosaic virus protein, (TMVP) and its tryptic peptide number 8 (residues 93-112 of the protein) exhibit cross-reactivity on the T cell level in some strains of mice (e.g., C3H.SW, C57BL/10); these strains are termed cross-reactive (CR). In other strains such as A/J or B10.BR, no cross-reactivity is exhibited; these strains are termed non-cross-reactive (NCR). Genetic experiments indicated that the cross-reactivity is dominant and that it is mapped to the I-A or I-E region of the MHC, with cross-reactivity exhibited by the I-Ab haplotype but not by I-Ak or I-Ek. Cell reconstitution experiments have indicated that the non-cross-reactivity is associated with the inability of the NCR APC to present Ag. Analysis of the area(s) on peptide 8 which serve(s) as epitope revealed that both strains recognize an overlapping area consisting of 11 amino acid residues in the middle of peptide 8 (residues 97-107), which by itself is nonstimulatory to TMVP- or peptide 8-immune T cells of the CR or the NCR strains. However, the addition of a few amino acid residues of the sequence of peptide 8 to this area converts it to a complete stimulatory epitope. Additivity experiments revealed that the CR strain contains two major T cell populations each recognizing this middle region of peptide 8 when elongated by a few amino acids N-terminally and C-terminally, respectively. In contrast, the NCR strain contains one major T cell population recognizing elongation only N-terminally. Because TMVP (but not peptide 8) requires processing before presentation to T cells, it is postulated that, during processing of TMVP, there occur alterations in the area of the proximal three or four N-terminal amino acids of the region consisting of peptide 8, destroying the only region containing the T cell epitope recognized by the NCR strain, hence TMVP and peptide 8 do not exhibit cross-reactivity in this strain. The same alterations of TMVP still leave intact an epitope consisting of amino acid residues C-terminal to the altered area which is recognized by the CR strain, hence the cross-reactivity exhibited by this strain. The results suggest that the difference in cross-reactivity on the T cell level between TMVP and peptide 8 exhibited by the strains may be due to differences in the orientation of presentation and the subsequent cell recognition of an epitope contained within peptide 8.(ABSTRACT TRUNCATED AT 400 WORDS)

Studies on the clonality of the response to an epitope of a protein antigen. Randomness of activation of epitope-recognizing clones and the development of clonal dominance.

Syngeneic mice immunized with tobacco mosaic virus protein (TMVP) can differ with respect to their ability to produce antibodies that bind a decapeptide epitope representing residues 103 to 112 of TMVP, and with respect to the fine specificity of the decapeptide binding antibodies as determined by their ability to bind several synthetic analogues of the decapeptide. To elucidate the mechanism responsible for the differences between the syngeneic animals in their ability to make anti-decapeptide antibodies, spleen cells from a large number of naive CSW mice were pooled, and aliquots were transferred (either including or excluding resident T cells) into naive recipients that were subsequently immunized with TMVP. Examination of the frequency and fine specificity of anti-decapeptide antibodies revealed that the recipients exhibited various clonalities of decapeptide binding antibody responses similar to those seen in a normal population of CSW mice. Moreover, the response of each individual mouse was of a restricted clonality despite the availability of a more extensive repertoire of decapeptide-recognizing clones. The results indicate that the selection of the clonality of the antibody response was not determined by the presence (or absence) of particular clones of B or T cells and that the mechanism responsible for generating differences between mice must have acted, subsequent to introduction of the Ag, by activation of a limited number of clones randomly selected by Ag and/or by Ag-driven mutation. The long term nature of the antibody response to the decapeptide epitope was also investigated. The response was shown to be "locked-in" for the life of the immunized individual. Thus, individuals that responded to TMVP but that did not produce antibodies to the decapeptide after the first set of immunizations with TMVP maintained their non-responsiveness to the decapeptide after the second set of immunizations with the protein. However, individuals that responded to an initial set of immunizations with TMVP by producing antibodies to the decapeptide epitope continue to produce antibodies to the decapeptide after a second set of immunizations with TMVP. The fine specificity of the decapeptide-binding antibodies also appeared to be "locked in" throughout the life of the immunized individual. The long term maintenance of the clonability of the antibody response does not appear to be influenced by Ag-specific T cells and is strictly a function of memory B cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Antigenic requirements for T-cell activation: reconstitution of a functional antigen from an inactive peptide portion of an antigen conjugated to protein carriers.

The structural features of an antigenic peptide required for T-cell activation were examined by a novel approach: an active antigen was constructed from an inactive peptide portion of the original antigen by conjugating it to various proteins. An eicosapeptide, peptide 8, representing residues 103-112 of the tobacco mosaic virus protein (TMVP), was utilized as the model antigen for these studies. While peptide 8 was able to stimulate, in vitro, T-cells from peptide 8 primed mice, synthetic peptides representing various portions of peptide 8 were unable to activate these cells. Although the amino-terminal undecapeptide of peptide 8 (residues 93-103 of TMVP) was unable to activate T-cells from peptide 8 primed mice, conjugates which consisted of this undecapeptide coupled to certain proteins were capable of inducing antigen-specific proliferation of these T-cells. These results identify two structural antigenic features essential for T-cell activation: a T-cell-recognizable epitope within the amino-terminal undecapeptide of peptide 8 and a second region provided by the carboxy-terminal half of peptide 8 or by protein carriers. Potential roles for this second region include providing a site for antigen interaction with Ia molecules on the antigen-presenting cell or, alternatively, providing amino acids important in stabilizing the binding of the T-cell antigen receptor. The results suggest that the recognition of this second region exhibits only a limited specificity.

Cell activation and immunogenicity.

There is presently great interest in the production of synthetic vaccines which utilize as immunogens peptides representing portions of protein antigens, either free or conjugated to protein carriers. The use of such immunogens raises questions regarding the cells which are activated an the characteristics of the resulting immune response. Using the tobacco mosaic virus protein (TMVP) as a model antigen, immune induction by the protein and by synthetic vaccines related to this protein was investigated. Specifically we have compared immune induction by the parent protein, an unconjugated eicosapeptide representing residues 93-112 of the protein, and an immunogen consisting of the C-terminal decapeptide of the above eicosapeptide conjugated to the protein carrier KLH. The comparison led to the following conclusions: Immunization with the free eicosapeptide but not with its C-terminal decapeptide leads to the activation of T and B lymphocytes. Immunization with the free eicosapeptide or with its C-terminal decapeptide-KLH conjugate induces antibodies capable of reacting with the parent protein. The isotype composition of the antibodies induced by these immunogens is similar to that induced by immunization with the whole protein. The fine specificity of the antibodies induced by all three immunogens is similar. However, the antibody populations induced by the synthetic immunogens may be devoid of one or more clonotypes depending upon constraints imposed by cellular interaction. Antigen specific T helper cells do not seem to influence the fine specificity of antibodies induced to a given epitope. Comparison of the induction of memory responses by the three immunogens led to the conclusion that immunization with the peptide hapten conjugated to the heterologous carrier KLH does not lead to an anamnestic antibody response upon encounter with the native protein. Immunization with an immunogenic peptide representing a portion of the protein recognized by T and B lymphocytes leads to an anamnestic antibody response upon encounter with the native protein.

Immune induction by a protein antigen and by a peptide segment of the protein.

The immune induction by a protein (the tobacco mosaic virus protein-TMVP) was compared to the immune induction by the free, non-conjugated eicosa tryptic peptide fragment of the protein (tryptic peptide 8 representing residues 93-112 of the protein). The results demonstrated that like TMVP, peptide 8 was immunogenic in A/J mice. TMVP and peptide 8 do not cross react on the T cell level. However, immunization with TMVP or with peptide 8 induces antibodies which react with both TMVP and peptide 8. Characterization of the antibodies produced by both immunogens revealed that: their isotope composition is similar with IgG1 and IgG2 being the predominant isotypes; this composition indicates that both immunogens are T cell dependent antigens, the antibodies induced by TMVP and by peptide 8 are directed against the C-terminal decapeptide portion of peptide 8 (residues 103-112 of the protein), the fine specificity of these antibodies is the same. These results, and results of adoptive transfer experiments, indicate that antigen specific T cells had no effect on the expression of the fine antibody specificity. The results demonstrate the feasibility of immunizing with a portion of a protein for the purpose of inducing antibodies with the same isotype composition and specificity towards a protein epitope as those induced by immunization with the whole protein.