Isolation and pharmacological characterization of AdTx1, a natural peptide displaying specific insurmountable antagonism of the alpha1A-adrenoceptor.

BACKGROUND AND PURPOSE: Venoms are a rich source of ligands for ion channels, but very little is known about their capacity to modulate G-protein coupled receptor (GPCR) activity. We developed a strategy to identify novel toxins targeting GPCRs. EXPERIMENTAL APPROACH: We studied the interactions of mamba venom fractions with alpha(1)-adrenoceptors in binding experiments with (3)H-prazosin. The active peptide (AdTx1) was sequenced by Edman degradation and mass spectrometry fragmentation. Its synthetic homologue was pharmacologically characterized by binding experiments using cloned receptors and by functional experiments on rabbit isolated prostatic smooth muscle. KEY RESULTS: AdTx1, a 65 amino-acid peptide stabilized by four disulphide bridges, belongs to the three-finger-fold peptide family. It has subnanomolar affinity (K(i)= 0.35 nM) and high specificity for the human alpha(1A)-adrenoceptor subtype. We showed high selectivity and affinity (K(d)= 0.6 nM) of radio-labelled AdTx1 in direct binding experiments and revealed a slow association constant (k(on)= 6 x 10(6).M(-1).min(-1)) with an unusually stable alpha(1A)-adrenoceptor/AdTx1 complex (t(1/2diss)= 3.6 h). AdTx1 displayed potent insurmountable antagonism of phenylephrine's actions in vitro (rabbit isolated prostatic muscle) at concentrations of 10 to 100 nM. CONCLUSIONS AND IMPLICATIONS: AdTx1 is the most specific and selective peptide inhibitor for the alpha(1A)-adrenoceptor identified to date. It displays insurmountable antagonism, acting as a potent relaxant of smooth muscle. Its peptidic nature can be exploited to develop new tools, as a radio-labelled-AdTx1 or a fluoro-labelled-AdTx1. Identification of AdTx1 thus offers new perspectives for developing new drugs for treating benign prostatic hyperplasia.

Proteome analysis of Aspergillus fumigatus identifies glycosylphosphatidylinositol-anchored proteins associated to the cell wall biosynthesis.

Previous studies in Aspergillus fumigatus (Mouyna I., Fontaine T., Vai M., Monod M., Fonzi W. A., Diaquin M., Popolo L., Hartland R. P., Latgé J.-P, J. Biol. Chem. 2000, 275, 14882-14889) have shown that a glucanosyltransferase playing an important role in fungal cell wall biosynthesis is glycosylphosphatidylinositol (GPI) anchored to the membrane. To identify other GPI-anchored proteins putatively involved in cell wall biogenesis, a proteomic analysis has been undertaken in A. fumigatus and the protein data were matched with the yeast genomic data. GPI-anchored proteins of A. fumigatus were released from membrane preparation by an endogenous GPI-phospholipase C, purified by liquid chromatography and separated by two-dimensional electrophoresis. They were characterized by their peptide mass fingerprint through matrix-assisted laser desorption/ionization-time of flight-(MALDI-TOF)-mass spectrometry and by internal amino acid sequencing. Nine GPI-anchored proteins were identified in A. fumigatus. Five of them were homologs of putatively GPI-anchored yeast proteins (Csa1p, Crh1p, Crh2p, Ecm33p, Gas1p) of unknown function but shown by gene disruption analysis to play a role in cell wall morphogenesis. In addition, a comparative study performed with chitin synthase and glucanosyl transferase mutants of A. fumigatus showed that a modification of the growth phenotype seen in these mutants was associated to an alteration of the pattern of GPI-anchored proteins. These results suggest that GPI-anchored proteins identified in this study are involved in A. fumigatus cell wall organization.

Contribution of partner switching and SpoIIAA cycling to regulation of sigmaF activity in sporulating Bacillus subtilis.

sigmaF, the first compartment-specific transcription factor in sporulating Bacillus subtilis, is negatively regulated by an anti-sigma factor, SpoIIAB. SpoIIAB has an alternative binding partner, SpoIIAA. To see whether (as has been proposed) SpoIIAB's binding preference for SpoIIAA or sigmaF depends on the nature of the adenine nucleotide present, we used surface plasmon resonance to measure the dissociation constants of the three complexes SpoIIAA-SpoIIAB-ADP, sigmaF-SpoIIAB-ADP, and sigmaF-SpoIIAB-ATP. The results suggested that SpoIIAB's choice of binding partner is unlikely to depend on the ATP/ADP ratio in the cell. The intracellular concentrations of sigmaF, SpoIIAB, SpoIIAA, and SpoIIAA-phosphate (SpoIIAA-P) were measured by quantitative immunoblotting between 0 and 3 h after the beginning of sporulation (t0 to t3). sigmaF and SpoIIAB were barely detectable at t0, but their concentrations increased in parallel to reach maxima at about t1.5. SpoIIAA-P increased steadily to a maximum at t3, but nonphosphorylated SpoIIAA was detectable only from t1.5, reached a maximum at t2.5, and then declined. Kinetic studies of the phosphorylation of SpoIIAA catalyzed by SpoIIAB suggested that the reaction was limited by a very slow release of one of the products (SpoIIAA-P or ADP) from SpoIIAB, with a turnover of about once per 20 min. This remarkable kinetic property provides an unexpected mechanism for the regulation of sigmaF. We propose that when SpoIIE (which dephosphorylates SpoIIAA-P) is active at the same time as SpoIIAB, SpoIIAA cycles repeatedly between the phosphorylated and nonphosphorylated forms. This cycling sequesters SpoIIAB in a long-lived complex and prevents it from inhibiting sigmaF.

Protein conformational change and nucleotide binding involved in regulation of sigmaF in Bacillus subtilis.

We have studied the ability of three mutant forms of SpoIIAA, containing amino acid substitutions at the site of phosphorylation (serine 58), to interact with SpoIIAB. Native gel analysis revealed that SpoIIAAS58A could form a complex with SpoIIAB in the presence of ADP and more strongly in the presence of ATP. SpoIIAAS58N did not form a complex with SpoIIAB in the presence of ADP but displayed some interaction with SpoIIAB in the presence of ATP. SpoIIAAS58D was unable to form a complex with SpoIIAB in the presence of either ADP or ATP. Corresponding differences were found in the behavior of the three mutant proteins when studied by gel permeation with high-performance liquid chromatography and limited proteolysis. SpoIIAAS58A behaved like the wild-type SpoIIAA, SpoIIAAS58D like SpoIIAA-P, and SpoIIAAS58N in a way that was intermediate between the behaviors of SpoIIAA and SpoIIAA-P. Limited proteolysis was also used to show that on binding of ADP or ATP SpoIIAB undergoes a shift in conformation. The affinity of SpoIIAB for ADP and ATP was determined by limited proteolysis in the presence of a wide range of nucleotide concentrations. The results indicated that SpoIIAB has approximately equal affinity for ADP and for ATP.

Compartmentalized distribution of the proteins controlling the prespore-specific transcription factor sigmaF of Bacillus subtilis.

BACKGROUND: Differential gene expression during sporulation in the prespore and mother cell of Bacillus subtilis is dependent on the correct timing and localization of the activity of specific transcription (sigma) factors. The first sigma factor activated is sigmaF, which directs gene expression specifically in the prespore compartment. Release of sigmaF activity is tightly controlled through a series of complex interactions involving an anti-sigma factor, SpoIIAB, an anti-anti-sigma factor SpoIIAA and a phosphoprotein phosphatase SpoIIE. In vitro studies have shown that SpoIIAB binds to sigmaF, preventing transcription of the sigmaF regulon, and that it can also phosphorylate SpoIIAA, thereby inactivating it. However, non-phosphorylated SpoIIAA can displace sigmaF from SpoIIAB. The SpoIIE phosphatase provides a means of reactivating SpoIIAA-P. RESULTS: We have directly determined the cellular distributions of sigmaF, SpoIIAB, SpoIIAA-P and SpoIIAA during sporulation, using recently developed immunofluorescence methods. While sigmaF activity is restricted to the prespore, the protein is present in both compartments. As development proceeds the sigmaF signal disappears. The anti-sigma factor SpoIIAB is also distributed throughout both cells and rapidly disappears from both cellular compartments soon after sigmaF becomes active. Disappearance of SpoIIAB seems to be closely associated with the activation of the second prespore-specific sigma factor sigmaF. The distribution of phosphorylated SpoIIAA closely mimics that of SpoIIAB, being non-compartmentalized and disappearing soon after sigmaF activation occurs. Significantly, the active, non-phosphorylated form of the anti-anti-sigma factor, SpoIIAA, accumulates in the prespore just before sigmaF becomes active. CONCLUSION: These results support the hypothesis that the accumulation of SpoIIAA within the prespore is the single most important requirement for activation of sigmaF.

Control of the cell-specificity of sigma F activity in Bacillus subtilis.

Sporulation in Bacillus subtilis is a simple developmental system involving the differentiation of two cell types that are formed by an asymmetric cell division. Major changes in the pattern of transcription during sporulation are brought about by the synthesis of new sigma factors (sigma), which are subunits of RNA polymerase that determine promoter specificity. Transcription in the smaller prespore cell type is initiated by a sigma factor called sigma F, the activity of which is subject to tight spatial and temporal control. It is negatively regulated by an anti-sigma factor, SpoIIAB, which is in turn controlled by an anti-anti-sigma factor, SpoIIAA. SpoIIAA and SpoIIAB participate in two contrasting reactions in vitro. In the presence of ATP, the proteins interact transiently and SpoIIAA is inactivated by phosphorylation on a specific serine residue; SpoIIAA then remains free to inhibit sigma F. In the presence of ADP, SpoIIAA binds tightly to SpoIIAB, and sigma F is set free. Release of sigma F activity in vivo might thus be effected by a prespore-specific reduction in the ATP/ADP ratio. Genetic experiments have implicated a fourth protein, called SpoIIE, in this system. It now appears that SpoIIE has two important and independent functions in the establishment of the prespore-specific transcription by sigma F. First it regulates sigma F activity, probably acting as a phosphatase to regenerate the active, non-phosphorylated form of SpoIIAA. Second it controls the formation of the septum that generates the prespore compartment. Combination of these two functions in a single polypeptide may provide a means of coupling gene expression with morphogenesis.

Bifunctional protein required for asymmetric cell division and cell-specific transcription in Bacillus subtilis.

During sporulation in Bacillus subtilis an asymmetric cell division gives rise to unequal progeny called the prepore and the mother cell. Gene expression in the prespore is initiated by cell-specific activation of the transcription factor sigma(F). Three proteins participate in the regulation of sigma(F) activity. The first, SpoIIAB, is an inhibitor of sigma(F), that is, an anti-sigma factor. SpoIIAB is also a protein kinase that catalyzes phosphorylation of the second regulatory protein SpoIIAA (the anti-anti-sigma factor), and thus inactivates it. A third protein, SpoIIE, was shown recently to be able to dephosphorylate SpoIIAA-P in vitro. Here we show that SpoIIE is a bifunctional protein with two critical roles in the establishment of cell fate. First, we confirm by the use of in vivo experiments that it regulates the release of sigma(F) activity by dephosphorylating SpoIIAA-P. Second, we show that SpoIIE is needed for normal formation of the asymmetric septum that separates the prespore from the mother cell. Combination of these two functions in a single polypeptide may serve to couple the release of the cell-specific transcription factors with the formation of the differentiating cells.

Establishing differential gene expression in sporulating Bacillus subtilis: phosphorylation of SpoIIAA (anti-anti-sigmaF) alters its conformation and prevents formation of a SpoIIAA/SpoIIAB/ADP complex.

Sigma-factor F (sigmaF) is a key transcription factor that initiates prespore development in Bacillus subtilis. Its activity is controlled by an anti-sigma factor, SpoIIAB, which is also a protein kinase that phosphorylates the anti-anti-sigma factor SpoIIAA. We have examined our earlier prediction that SpoIIAA must undergo a major change in its properties when phosphorylated. Upon gel filtration in the presence of ADP, SpoIIAA-P was eluted from a Superdex column much later than SpoIIAB, whereas SpoIIAA was coeluted with SpoIIAB, indicating the formation of a protein/protein complex. The complex contained ADP, and had two monomers of SpoIIAA to each SpoIIAB dimer. Its dissociation constant was 13 mu M. Gel permeation on high-performance liquid chromatography (HPLC) suggested an apparent molecular mass for SpoIIAA-P which was much higher (23.5 kDa) than that of SpoIIAA (15.8 kDa), but Ferguson plots showed that SpoIIAA-P was not a phosphorylated dimer of SpoIIAA. Our tentative conclusion, that SpoIIAA and SpoIIAA-P differ markedly in conformation, was confirmed by the results of partial digestion with chymotrypsin.

The Tonoplast H+-ATPase of Acer pseudoplatanus Is a Vacuolar-Type ATPase That Operates with a Phosphoenzyme Intermediate.

The tonoplast H+-ATPase of Acer pseudoplatanus has been purified from isolated vacuoles. After solubilization, the purification procedure included size-exclusion and ion-exchange chromatography. The H+-ATPase consists of at least eight subunits, of 95, 66, 56, 54, 40, 38, 31, and 16 kD, that did not cross-react with polyclonal antibodies raised to the plasmalemma ATPase of Arabidopsis thaliana. The 66-kD polypeptide cross-reacted with monoclonal antibodies raised to the 70-kD subunit of the vacuolar H+-ATPase of oat roots. The functional molecular size of the tonoplast H+-ATPase, analyzed in situ by radiation inactivation, was found to be around 400 kD. The 66-kD subunit of the tonoplast H+-ATPase was rapidly phosphorylated by [[gamma]-32P]ATP in vitro. The complete loss of radio-activity in the 66-kD subunit after a short pulse-chase experiment with unlabeled ATP reflected a rapid turnover, which characterizes a phosphorylated intermediate. Phosphoenzyme formed from ATP is an acylphosphate-type compound as shown by its sensitivity to hydroxylamine and alkaline pH. These results lead us to suggest that the tonoplast H+-ATPase of A. pseudoplatanus is a vacuolar-type ATPase that could operate with a plasmalemma-type ATPase catalytic mechanism.

Role of interactions between SpoIIAA and SpoIIAB in regulating cell-specific transcription factor sigma F of Bacillus subtilis.

Genetic experiments have suggested that sigma F, the first compartment-specific transcription factor in sporulating B. subtilis, is regulated by an anti-sigma factor SpoIIAB and an anti-anti-sigma factor SpoIIAA. Previously, we reported biochemical results demonstrating that SpoIIAB is both a phosphokinase whose substrate is SpoIIAA and an inhibitor of sigma F-directed transcription. We now show that in the presence of SpoIIAB and ATP or ADP, SpoIIAA can undergo two alternative reactions. When ATP is present, SpoIIAA is phosphorylated rapidly and completely to SpoIIAA-phosphate, and SpoIIAB is immediately released; but in the presence of ADP, SpoIIAA forms a long-lasting complex with SpoIIAB. ADP is an inhibitor of the phosphorylation by ATP. Furthermore, we have mutated SpoIIAA at residue Ser 58, the target for phosphorylation, to aspartate or alanine. SpoIIAAS58D, which apparently resembles SpoIIAA-phosphate, is unable to make a complex with SpoIIAB and is devoid of anti-anti-sigma F activity, whereas SpoIIAAS58A, which cannot be phosphorylated, makes complexes with SpoIIAB in the presence of ADP or ATP and has constitutive anti-anti-sigma F activity both in vivo and in vitro. It seems likely that the alternative reactions of SpoIIAA and SpoIIAB, involving ADP or ATP, regulate the anti-anti-sigma capacity of SpoIIAA and hence the activity of sigma F.

[Effect of vanadate on the vacuolar ATPase of Acer pseudoplatanus]. / Effet du vanadate sur l'ATPase vacuolaire d'Acer pseudoplatanus.

The ATPase of vacuoles isolated from Acer pseudoplatanus cells is strongly inhibited by vanadate, a specific inhibitor of plasma membrane ATPase. The degree of inhibition depends upon the ionic composition, ATP and magnesium concentrations of the reaction medium and the inhibition is reversed by EDTA which complexes vanadate. In absence of factor which may interfere with the effectiveness of inhibitor, vanadate inhibits the ATPase non-competitively.