FcγRI is required for TGFß2-treated macrophage-induced tolerance.

Macrophages treated with TGFß2 (TGFß2-Mϕ) and antigen are highly tolerogenic in vivo, and induce antigen-specific and long-lasting tolerance in both naïve and primed mice via induction of suppressor/regulatory T cells. In this study, we examined the molecular pathways, including the requirements for Smad-dependent signaling, that are involved in the induction and function of tolerogenic TGFß2-Mϕ. Treatment of murine macrophages with TGFß2 induced translocation of Smad2/3 to the nucleus, and impairment of Smad3-, but not Smad2-, dependent signaling inhibited the tolerogenic function of a TGFß2-treated murine macrophage cell line. Gene expression in murine macrophages treated with TGFß2 was evaluated by microarray analysis. The FcγRI gene was one of a number of immune-related genes differentially expressed in TGFß2-Mϕ, and appeared to be critical for tolerance in this system, since TGFß2-Mϕ from FcγRI deficient mice were unable to induce tolerance. The role that FcγRI plays in TGFß2-Mϕ-mediated tolerance is currently unclear. The results of this study provide important information about the factors that are critical for the induction of TGFß2-Mϕ-mediated tolerance, and a better understanding of these mechanisms could lead to the development of more effective tolerance-inducing strategies for the treatment of autoimmune/inflammatory diseases.

Functional analysis of CBP/p300 in embryonic orofacial mesenchymal cells.

CREB binding protein (CBP) and the close structural homolog, p300, are nuclear coactivators of multiple signaling pathways that play important roles in embryonic development and cellular homeostasis. TGFbeta regulates the proliferation rate of many cell types and has been demonstrated to inhibit the growth rate of mouse embryonic maxillary mesenchymal (MEMM) cells. The role of CBP and p300 in TGFbeta-mediated control of proliferation of MEMM cells was thus investigated using an in vitro gene knockdown approach. TGFbeta reporter assays demonstrated that p300 mRNA knockdown via targeted siRNAs led to a reduction in the response to TGFbeta, whereas knockdown of CBP by the same approach had an insignificant effect. In MEMM cell proliferation assays, siRNA-mediated knockdown of CBP and/or p300 had little impact upon TGFbeta-mediated growth inhibition; however, the basal rate of proliferation was increased. Inhibition of p300 activity via overexpression of a dominant-negative mutant (p300deltaC/H3) led to significant inhibition of TGFbeta-mediated activation of p3TP-lux. As with the siRNA knockdown approach, p300deltaC/H3 also increased the basal rate of cell proliferation of MEMM cells. CBP/p300 siRNA knockdown had a significant but incomplete inhibition of TGFbeta-induction of matrix metalloproteinase-9 (gelatinase B) expression. These data demonstrate that p300 is involved in Smad-mediated transcription of p3TP-lux, however, its role (and that of CBP) in biological processes such as the control of cell proliferation and extracellular matrix metabolism is more complex and may be mediated via mechanisms beyond coactivator recruitment.

Interaction between Smad 3 and Dishevelled in murine embryonic craniofacial mesenchymal cells.

OBJECTIVES: To determine the in vivo interaction between Smad 3 and Dishevelled-1. DESIGN: Cell culture transfection followed by immunoprecipitation with specific antibodies. SETTING AND SAMPLE POPULATION: The Department of Molecular, Cellular, and Craniofacial Biology, Birth Defects Center, University of Louisville. EXPERIMENTAL VARIABLE: Overexpression of myc-Smad 3. OUTCOME MEASURE: Western blotting of anti-Dishevelled immunoprecipitates for Smad 3. RESULTS: Smad 3 and Dishevelled isoforms-1, -2, and -3 all bind Smad 3 in glutathione-S-transferase (GST) pull-down assays and Smad 3 binds to Dishevelled-1 in vivo. Stimulation of the transforming growth factor beta (TGFbeta) pathway leads to increased binding of Smad 3 and Dishevelled-1 in vivo. CONCLUSION: Smad 3 binds all three known isoforms of Dishevelled and binds Dishevelled 1 in vivo. TGFbeta signaling modulates the interaction between Smad 3 and Dishevelled-1.

Nuclear convergence of the TGFbeta and cAMP signal transduction pathways in murine embryonic palate mesenchymal cells.

Transforming growth factors beta (TGFbeta) and cyclic AMP (cAMP) both participate in growth and differentiation of the developing mammalian secondary palate and elicit similar biological responses. Cross-talk between these two signal transduction pathways in cells derived from the embryonic palate has been demonstrated previously. In the present study, we have examined nuclear convergence of these signalling pathways at the level of transcriptional complex formation. Biotinylated oligonucleotides encoding a consensus Smad binding element (SBE), or a cyclic AMP response element (CRE), were mixed with cell extracts from murine embryonic palate mesenchymal (MEPM) cells that were treated with either TGFbeta or forskolin. Protein-oligonucleotide complexes were precipitated with streptavidin-agarose, and analysed by Western blotting to identify proteins in the complex bound to each consensus oligonucleotide. TGFbeta treatment of MEPM cells increased the levels of phosphorylated Smad2, phosphorylated cAMP response element binding protein (CREB), and the coactivator, CREB binding protein (CBP), that were part of a complex bound to the SBE. Treatment of cells with forskolin, a stimulator of adenylate cyclase, increased the amount of phosphorylated CREB and CBP, but not the amount of phosphorylated Smad2 bound in a complex to the SBE. Additionally, the presence of the co-repressors, c-Ski and SnoN, was demonstrated as part of a complex bound to the SBE (but not the CRE). Amounts of c-Ski and SnoN found in the SBE-containing complex increased in response to either TGFbeta or forskolin. These results demonstrate that phosphorylated CREB forms a complex with the co-activator CBP, phosphorylated Smad2 and the co-repressors c-Ski and SnoN on a consensus SBE. This suggests cooperative regulation of genes with SBE-containing promoters by the cAMP and TGFbeta signalling pathways in the developing palate.

Expression of the nuclear coactivators CBP and p300 in developing craniofacial tissue.

cAMP regulatory element-binding protein (CREB)-binding protein (CBP) and its functional homolog, the adenovirus E1A -associated 300-kDa protein (p300) are nuclear coactivators and histone acetyltransferases that integrate signals from disparate pathways by bridging specific transcription factors to the basal transcription apparatus. Their role in patterning and development was suggested by studies in mice in which CBP and p300 expression was disrupted and by the human Rubinstein-Taybi syndrome, which is associated with mutations of CBP. The cAMP signal transduction pathway plays a critical role during development of the palate. The linkage between cAMP and expression of specific genes is mediated via activation of trans-acting deoxyribonucleic acid-binding proteins such as the nuclear CREB. For genes regulated by CBP- or p300-containing transcriptional complexes, rates of transcription will depend in part on cellular levels and distribution of CBP/p300. We have thus determined the temporal and spatial expression of CBP and p300 in murine embryonic palatal tissue. Both CBP and p300 proteins and messenger ribonucleic acids are expressed in palatal tissue on each d of palate development (days 12-14 of gestation), as measured by Western blotting and reverse-transcription polymerase chain reaction. Expression of both CBP and p300 was greatest on day 12 of gestation, suggesting that these transcriptional coactivators are developmentally regulated. Immunohistochemical analysis of CBP and p300 expression in the murine embryonic craniofacial region revealed a ubiquitous distribution for both proteins. These studies lay the groundwork for further investigations into the role of CBP and p300 in cellular signaling during craniofacial development.

Endocrine manifestations of stimulatory G protein alpha-subunit mutations and the role of genomic imprinting.

The heterotrimeric G protein G(s) couples hormone receptors (as well as other receptors) to the effector enzyme adenylyl cyclase and is therefore required for hormone-stimulated intracellular cAMP generation. Receptors activate G(s) by promoting exchange of GTP for GDP on the G(s) alpha-subunit (G(s)alpha) while an intrinsic GTPase activity of G(s)alpha that hydrolyzes bound GTP to GDP leads to deactivation. Mutations of specific G(s)alpha residues (Arg(201) or Gln(227)) that are critical for the GTPase reaction lead to constitutive activation of G(s)-coupled signaling pathways, and such somatic mutations are found in endocrine tumors, fibrous dysplasia of bone, and the McCune-Albright syndrome. Conversely, heterozygous loss-of-function mutations may lead to Albright hereditary osteodystrophy (AHO), a disease characterized by short stature, obesity, brachydactyly, sc ossifications, and mental deficits. Similar mutations are also associated with progressive osseous heteroplasia. Interestingly, paternal transmission of GNAS1 mutations leads to the AHO phenotype alone (pseudopseudohypoparathyroidism), while maternal transmission leads to AHO plus resistance to several hormones (e.g., PTH, TSH) that activate G(s) in their target tissues (pseudohypoparathyroidism type IA). Studies in G(s)alpha knockout mice demonstrate that G(s)alpha is imprinted in a tissue-specific manner, being expressed primarily from the maternal allele in some tissues (e.g., renal proximal tubule, the major site of renal PTH action), while being biallelically expressed in most other tissues. Disrupting mutations in the maternal allele lead to loss of G(s)alpha expression in proximal tubules and therefore loss of PTH action in the kidney, while mutations in the paternal allele have little effect on G(s)alpha expression or PTH action. G(s)alpha has recently been shown to be also imprinted in human pituitary glands. The G(s)alpha gene GNAS1 (as well as its murine ortholog Gnas) has at least four alternative promoters and first exons, leading to the production of alternative gene products including G(s)alpha, XLalphas (a novel G(s)alpha isoform that is expressed only from the paternal allele), and NESP55 (a chromogranin-like protein that is expressed only from the maternal allele). A fourth alternative promoter and first exon (exon 1A) located approximately 2.5 kb upstream of the G(s)alpha promoter is normally methylated on the maternal allele and transcriptionally active on the paternal allele. In patients with isolated renal resistance to PTH (pseudohypoparathyroidism type IB), the exon 1A promoter region has a paternal-specific imprinting pattern on both alleles (unmethylated, transcriptionally active), suggesting that this region is critical for the tissue-specific imprinting of G(s)alpha. The GNAS1 imprinting defect in pseudohypoparathyroidism type IB is predicted to decrease G(s)alpha expression in renal proximal tubules. Studies in G(s)alpha knockout mice also demonstrate that this gene is critical in the regulation of lipid and glucose metabolism.

A mutation in the heterotrimeric stimulatory guanine nucleotide binding protein alpha-subunit with impaired receptor-mediated activation because of elevated GTPase activity.

It has been reported that substitution of Arg258, a residue within the GTPase domain of the heterotrimeric guanine nucleotide binding protein (G protein) alpha-subunit (alphas), to alanine (alphas-R258A) results in decreased activation by receptor or aluminum fluoride (AlF4-) and increased basal GDP release. Arg258 interacts with Gln170 in the helical domain, and, presumably, loss of this interaction between the GTPase and helical domain leads to more rapid GDP release, resulting in decreased activation by AlF4- and increased thermolability. In this study, we mutate Gln170 to alanine (alphas-Q170A) and demonstrate that this mutant, like alphas-R258A, has decreased activation by AlF4-, increased thermolability (both reversed in the presence of excess guanine nucleotide), and an increased rate of GDP release. However, unlike alphas-R258A, alphas-Q170A does not have impaired receptor-mediated activation. Therefore, this interdomain interaction is critical to maintain normal guanine nucleotide binding (and hence normal activation by AlF4-) but is not important for receptor-mediated activation. In single turnover GTPase assays, the catalytic rate for GTP hydrolysis of alphas-R258A was 14-fold higher than normal whereas that of alphas-Q170A was unaffected. Examination of the alphas crystal structure suggests that Arg258, through interactions with Glu50, might constrain the position of Arg201, a residue critical for catalyzing the GTPase reaction. This is an example of a mutation in a heterotrimeric G protein that results in an increased intrinsic GTPase activity and provides another mechanism by which G protein mutations can impair signal transduction.

Mutagenesis of the conserved residue Glu259 of Gsalpha demonstrates the importance of interactions between switches 2 and 3 for activation.

We previously reported that substitution of Arg258 within the switch 3 region of Gsalpha impaired activation and increased basal GDP release due to loss of an interaction between the helical and GTPase domains (Warner, D. R., Weng, G., Yu, S., Matalon, R., and Weinstein, L. S. (1998) J Biol. Chem. 273, 23976-23983). The adjacent residue (Glu259) is strictly conserved in G protein alpha-subunits and is predicted to be important in activation. To determine the importance of Glu259, this residue was mutated to Ala (Gsalpha-E259A), Gln (Gsalpha-E259Q), Asp (Gsalpha-E259D), or Val (Gsalpha-E259V), and the properties of in vitro translation products were examined. The Gsalpha-E259V was studied because this mutation was identified in a patient with Albright hereditary osteodystrophy. S49 cyc reconstitution assays demonstrated that Gsalpha-E259D stimulated adenylyl cyclase normally in the presence of GTPgammaS but was less efficient with isoproterenol or AlF4-. The other mutants had more severely impaired effector activation, particularly in response to AlF4-. In trypsin protection assays, GTPgammaS was a more effective activator than AlF4- for all mutants, with Gsalpha-E259D being the least severely impaired. For Gsalpha-E259D, the AlF4--induced activation defect was more pronounced at low Mg2+ concentrations. Gsalpha-E259D and Gsalpha-E259A purified from Escherichia coli had normal rates of GDP release (as assessed by the rate GTPgammaS binding). However, for both mutants, the ability of AlF4- to decrease the rate of GTPgammaS binding was impaired, suggesting that they bound AlF4- more poorly. GTPgammaS bound to purified Gsalpha-E259D irreversibly in the presence of 1 mM free Mg2+, but dissociated readily at micromolar concentrations. Sucrose density gradient analysis of in vitro translates demonstrated that all mutants except Gsalpha-E259V bind to beta gamma at 0 degreesC and were stable at higher temperatures. In the active conformation Glu259 interacts with conserved residues in the switch 2 region that are important in maintaining both the active state and AlF4- in the guanine nucleotide binding pocket. Although both Gsalpha Arg258 and Glu259 are critical for activation, the mechanisms by which these residues affect Gsalpha protein activation are distinct.

A novel mutation in the switch 3 region of Gsalpha in a patient with Albright hereditary osteodystrophy impairs GDP binding and receptor activation.

Albright hereditary osteodystrophy (AHO), a disorder characterized by skeletal abnormalities and obesity, is associated with heterozygous inactivating mutations in the gene for Gsalpha. A novel Gsalpha mutation encoding the substitution of tryptophan for a nonconserved arginine within the switch 3 region (Gsalpha R258W) was identified in an AHO patient. Although reverse transcription-polymerase chain reaction studies demonstrated that mRNA expression from wild type and mutant alleles was similar, Gsalpha expression in erythrocyte membranes from the affected patient was reduced by 50%. A Gsalpha R258W cDNA, as well as one with arginine replaced by alanine (Gsalpha R258A), was generated, and the biochemical properties of in vitro transcription/translation products were examined. When reconstituted with cyc- membranes, both mutant proteins were able to stimulate adenylyl cyclase normally in the presence of guanosine- 5'-O-(3-thiotriphosphate) (GTPgammaS) but had decreased ability in the presence of isoproterenol or AlF4- (a mixture of 10 microM AlCl3 and 10 mM NaF). The ability of each mutant to bind and be activated by GTPgammaS or AlF4- was assessed by trypsin protection assays. Both mutants were protected normally by GTPgammaS but showed reduced protection in the presence of AlF4-. The addition of excess GDP (2 mM) was able to rescue the ability of AlF4- to protect the mutants, suggesting that they might have reduced affinity for GDP. A Gsalpha R258A mutant purified from Escherichia coli had decreased affinity for GDP and an apparent rate of GDP release that was 10-fold greater than that of wild type Gsalpha. Sucrose density gradient analysis demonstrated that both Gsalpha R258W and Gsalpha R258A were thermolabile at higher temperatures and that denaturation of both mutants was prevented by the presence of 0.1 mM GTPgammaS or 2 mM GDP. The crystal structure of Gsalpha demonstrates that Arg258 interacts with a conserved residue in the helical domain (Gln170). Arg258 substitutions would be predicted to open the cleft between the GTPase and helical domains, allowing for increased GDP release in the inactive state, resulting in enhanced thermolability and reduced AlF4--induced adenylyl cyclase stimulation and trypsin protection, since activation by AlF4- requires bound GDP.

A novel mutation adjacent to the switch III domain of G(S alpha) in a patient with pseudohypoparathyroidism.

A novel G(S alpha) mutation encoding the substitution of arginine for serine 250 (G[S alpha] S250R) was identified in a patient with pseudohypoparathyroidism type Ia. Both G(S) activity and G(S alpha) expression were decreased by about 50% in erythrocyte membranes from the affected patient. The cDNA of this G(S alpha) mutant, as well as one in which the S250 residue is deleted (G[S alpha]-deltaS250), was generated, and the biochemical properties of the products of in vitro transcription/translation were examined. Both mutants had a sedimentation coefficient similar to that of wild type G(S alpha) (approximately 3.7S) when kept at 0 C after synthesis. However when maintained for 1-2 h at 30-37 C, both mutants aggregated to a material sedimenting at approximately 6.3S or greater (G[S alpha]-S250R to a greater extent than G(S alpha]-deltaS250), while wild type G(S alpha) sedimented at approximately 3.7S, suggesting that the mutants were thermolabile. Incubation in the presence of high doses of guanine nucleotide partially prevented heat denaturation of G(S alpha) deltaS250 but had no protective effect on G(S alpha-S250R. Sucrose density gradient centrifugation at 0 C in the presence and absence of beta gamma-dimers demonstrated that, in contrast to wild type G(S alpha) neither mutant could interact with beta gamma. Trypsin protection assays revealed no protection of G(S alpha)-S250R by GTPgammaS or AIF4- at any temperature. GTPgammaS conferred modest protection of G(S alpha)-deltaS250 (approximately 50% of wild-type G[S alpha]) at 30 C but none at 37 C, while AIF4- conferred slight protection at 20 C but none at 30 C or above. Consistent with this result, G(S alpha)-deltaS250 was able to stimulate adenylyl cyclase at 30 C when reconstituted with cyc- membranes in the presence of GTPgammaS but not in the presence of AIF4-. G(S alpha)-S250R showed no ability to stimulate adenylyl cyclase in the presence of either agent. Stable transfection of mutant and wild-type G(S alpha) into cyc- S49 lymphoma cells revealed that the majority of wild type G(S alpha) localized to membranes, while little or no membrane localization occurred for either mutant. Modeling of G(S alpha) based upon the crystal structure of G(t alpha) or G(i alpha) suggests that Ser250 interacts with several residues within and around the conserved NKXD motif, which directly interacts with the guanine ring of bound GDP or GTP. It is therefore possible that substitution or deletion of this residue may alter guanine nucleotide binding, which could lead to thermolability and impaired function.

Does subunit dissociation necessarily accompany the activation of all heterotrimeric G proteins?

Heterotrimeric (alpha beta gamma) G proteins mediate a variety of signal transduction events in virtually every cell of every eukaryotic organism. The predominant hypothesis is that dissociation of the alpha-subunit from the G beta gamma-subunit complex necessarily accompanies the activation of these proteins, and that the alpha-subunit is primarily responsible for regulating the response of effector molecules. However, there is increasing evidence that both the alpha-subunit and the beta gamma-subunit complex function in regulating effector activity. Furthermore, data for some G proteins suggest that they function as activated heterotrimers rather than as dissociated subunits.

Suicide inactivation of thioether S-methyltransferase by ethyl sulfide.

Thioether S-methyltransferase is an important enzyme in the metabolism of sulfur and selenium-containing compounds in animals. Ethyl vinyl sulfide was previously shown to be a substrate for this enzyme yielding methyl ethyl vinyl sulfonium ion (MEVS+) upon reaction with S-adenosylmethionine. Since vinyl sulfonium ions are reactive toward nucleophiles, the inactivation of thioether S-methyltransferase as a result of its methylation of ethyl vinyl sulfide was investigated. Ethyl vinyl sulfide was found to inactivate thioether S-methyltransferase in a time-dependent, pseudo-first-order process with k(inact) and KI values of 0.05 min(-1) and 0.275 mM, respectively. Calculation of the partition ratio revealed one inactivation event for every 100 turnovers. Dimethyl sulfide, an alternate substrate for thioether S-methyltransferase which yields the nonreactive product trimethyl sulfonium ion, protected the enzyme from inactivation by ethyl vinyl sulfide. The inactivation is a result of covalent reaction of methyl ethyl vinyl sulfonium ion with the enzyme as shown by comigration of radioactivity with the enzyme during denaturing gel filtration of reaction mixtures containing thioether S-methyltransferase, ethyl vinyl sulfide, and S-adenosyl[methyl-3H]methionine. Using this method the stoichiometry of inactivation was determined to be 1 mol of [3H]-methyl group/mol of thioether S-methyltransferase inactivated. Both the alternate substrate, dimethyl sulfide, and the competitive product inhibitor, S-adenosylhomocysteine, inhibited such covalent labeling of the enzyme by ethyl vinyl sulfide and S-adenosyl[methyl-3H]methionine. Chemically synthesized MEVS+ inactivated thioether S-methyltransferase, and [methyl-14C]MEVS+ covalently labeled the enzyme with 14C. These results reveal a previously unrecognized mechanism for biochemical activation of vinyl thioethers by methylation to form reactive vinyl sulfonium ions.

Altered Gs alpha N-terminus affects Gs activity and interaction with the G beta gamma subunit complex in cell membranes but not in solution.

The stimulatory G protein (Gs) mediates activation of adenylylcyclase by a ligand-receptor complex. Gs is heterotrimeric (alpha beta gamma) and activation can be accomplished by dissociation of the alpha-subunit (Gs alpha) from the beta gamma-subunit complex (G beta gamma). Gs alpha is also a substrate for choleragen catalyzed ADP-ribosylation when it is associated with G beta gamma but not as free Gs alpha. Using recombinant DNA techniques we modified the cDNA for the 52,000 M(r) form of Gs alpha (Gs alpha 52) to produce a protein with a 2,400 M(r) N-terminal extension (Gs alpha 54.4). This N-terminal extension could be removed with the protease Factor Xa. In vitro transcription and translation of the recombinant plasmid containing the cDNA's for Gs alpha 52 and Gs alpha 54.4 produced a 52,000 M(r) and a 54,000 M(r) protein, respectively. In solution the properties of Gs alpha 52 and Gs alpha 54.4 were indistinguishable. Both proteins: (a) formed a heterotrimer with G beta gamma and their affinities for the subunit complex were the same; (b) could be ADP-ribosylated by choleragen in the presence but not in the absence of G beta gamma; (c) bound the non-hydrolyzable GTP analogue, GTP gamma S, and were protected from chymotryptic proteolysis by the guanine nucleotide; and (d) could activate in vitro translated type IV adenylylcyclase. Gs alpha 54.4 and Gs alpha 52 were incorporated into S49 cyc-membranes, which lack Gs alpha. After incorporation, both Gs alpha 52 and Gs alpha 54.4 were protected from chymotryptic proteolysis when GTP gamma S was present, revealing that both proteins were able to bind the nucleotide and undergo a conformational change characteristic of Gs alpha activation. When Gs alpha 52 was incorporated into cyc-membranes it could mediate both hormone and GTP gamma S stimulation of adenylylcyclase and could be ADP-ribosylated by choleragen, but Gs alpha 54.4 could do neither of these things, indicating that the properties of Gs alpha 54.4 were altered by the membrane. Deletion of the N-terminal extension by treatment with Factor Xa in solution converted Gs alpha 54.4 to Gs alpha 52, and upon incorporation into cyc-membranes it behaved like Gs alpha 52 in every regard, showing that the effect of the N-terminal extension was reversible. A lack of other differences in the functional properties of Gs alpha 52 and Gs alpha 54.4 suggests a correlation between the interaction of Gs alpha with G beta gamma and its ability to activate adenylylcyclase.

Cell-free synthesis of functional type IV adenylyl cyclase.

Type IV adenylyl cyclase was synthesized in a cell-free coupled transcription and translation system. Radiolabeled type IV adenylyl cyclase was specifically immune precipitated with anti-ACIV antibodies. The molecular weight of in vitro translated type IV adenylyl cyclase was 110,000, similar to that for type IV adenylyl cyclase produced in the baculovirus system [B. Gao and A. G. Gilman, (1991) Proc. Natl. Acad. Sci. USA 88, 10178-10182]. Dimyristoyl phosphatidylcholine was required for efficient stimulation of activity by both forskolin and GS, with a maximum specific activity of 700 +/- 100 nmol cAMP.min-1.mg-1 attained with both effectors combined. Both bovine brain GS and in vitro translated GS alpha activated in vitro translated type IV adenylyl cyclase; however, G beta gamma only enhanced stimulation in the presence of in vitro translated GS alpha. Forskolin maximally activated at concentrations from 200 to 400 microM in the absence or presence of GS. The in vitro translated product was very stable as production of cAMP by forskolin/GS activated type IV adenylyl cyclase was linear for up to 90 min at 30 degrees C.

Cloning and base sequence analysis of a cDNA encoding mouse lung thioether S-methyltransferase.

Thioether S-methyltransferase catalyzes transfer of the methyl group from S-adenosylmethionine to X in compounds of the structure R-X-R', where X may be sulfur, selenium, or tellurium, and R and R' may be various organic groups. To obtain a cDNA clone of thioether S-methyltransferase, a mouse lung cDNA library in lambda gt11 was screened with a 99 base-pair probe obtained by performing the polymerase chain reaction on oligo(dT) primed, reverse transcribed, mouse lung RNA using two degenerate primers designed from partial amino-acid sequences of the enzyme. The entire coding and 3'-untranslated regions were obtained and sequenced. The predicted protein contains 264 amino-acid residues and has a calculated M(r) of 29,460. The amino-acid sequence of thioether S-methyltransferase contains three motifs characteristic of many methyltransferases and has a high level of identity with the amino-acid sequences of nicotinamide N-methyltransferase and phenylethanolamine N-methyltransferase. However, in spite of the fact that they are both mammalian cytosolic sulfur methyltransferases, the sequences of thioether S-methyltransferase and thiopurine S-methyltransferase share little identity.

Se-(8-azidoadenosyl)[75Se]selenomethionine as a photoaffinity label for S-adenosylmethionine binding proteins.

A method is described for the synthesis and purification of the photoaffinity label Se-(8-azidoadenosyl)[75Se]selenomethionine. This photoaffinity label can be used to specifically and covalently label the S-adenosylmethionine binding site of proteins that use this cofactor, as exemplified by labeling of thioether methyltransferase. By utilizing the gamma-emitting isotope of selenium, Se-(8-azidoadenosyl)[75Se]selenomethionine eliminates the need for the impregnation of acrylamide gels with fluorographic enhancers and dilution of liquid samples into scintillation cocktails, as is required with the commonly used methyl-3H-labeled and 35S-labeled S-(8-azidoadenosyl)methionine.