TbPDE1, a novel class I phosphodiesterase of Trypanosoma brucei.

Cyclic nucleotide specific phosphodiesterases (PDEs) are important components of all cAMP signalling networks. In humans, 11 different PDE families have been identified to date, all of which belong to the class I PDEs. Pharmacologically, they have become of great interest as targets for the development of drugs for a large variety of clinical conditions. PDEs in parasitic protozoa have not yet been extensively investigated, despite their potential as antiparasitic drug targets. The current study presents the identification and characterization of a novel class I PDE from the parasitic protozoon Trypanosoma brucei, the causative agent of human sleeping sickness. This enzyme, TbPDE1, is encoded by a single-copy gene located on chromosome 10, and it functionally complements PDE-deficient strains of Saccharomyces cerevisiae. Its C-terminal catalytic domain shares about 30% amino acid identity, including all functionally important residues, with the catalytic domains of human PDEs. A fragment of TbPDE1 containing the catalytic domain could be expressed in active form in Escherichia coli. The recombinant enzyme is specific for cAMP, but exhibits a remarkably high Km of > 600 microm for this substrate.     

cAMP signalling in the kinetoplastid protozoa

Several species of kinetoplastid protozoa cause major human infectious diseases. Trypanosoma cruzi is responsible for the fatal Chagas disease in large parts of South America, the various species of Leishmania cause a number of different human diseases with millions of patients world-wide, and the African trypanosome Trypanosoma brucei is the agent of human sleeping sickness, a disastrously re-emerging epidemic of fatal infections in Sub-Saharan Africa. Chemotherapy of all of these infections is in a very unsatisfactory state. cAMP signalling pathways in humans have provided interesting drug targets for a number of clinical conditions, from asthma to impotency. Similarly, cAMP signalling in kinetoplastids might offer useful targets for the development of novel antiparasitic drugs, which makes their exploration an urgent need. Current knowledge suggests that cAMP signalling proceeds along very similar pathways in all kinetoplastid pathogens (T. cruzi, the Leishmanias and T. brucei). Their adenylyl cyclases are structurally very different from the human enzymes and appear to function as enzyme-linked cell surface receptors. They might represent the major sensory apparatus of the kinetoplastids, guiding much of their environmental sensing and host/parasite interaction. The cAMP-specific phosphodiesterases of the kinetoplastids are rather similar to those of human cells and might function in similar ways. Essentially nothing is known on downstream effectors of cAMP in the kinetoplastids. Homologues of protein kinase A and its regulatory subunits have been identified, but their biochemical properties seem to be disctinct from that of mammalian protein kinase A.     

The adenylyl cyclase family

Hormone-sensitive adenylyl cyclase is a model system for the study of receptor-mediated signal transduction. It is comprised of three types of components: 1) receptors for hormones that regulate cyclic AMP (cAMP) synthesis, 2) regulatory GTP binding proteins (G proteins), and 3) the family of enzymes, the adenylyl cyclases. Concentrations of cAMP are altered by at least 35 different stimulatory or inhibitory hormones and neurotransmitters. Other signalling pathways may also influence cAMP production through regulation of particular adenylyl cyclase subtypes. The second messenger, cAMP propagates the hormone signal through the effects of cAMP-dependent protein kinase.While structural information on the adenylyl cyclases is limited, a cDNA clone for a calmodulin-sensitive form of bovine brain adenylyl cyclase has been isolated. The amino acid sequence encoded by the Type I cDNA is approximately 40% identical to those specified by three other adenylyl cyclase cDNAs that have been cloned subsequently. This degree of structural variation implies that there must be functional differences between the adenylyl cyclases.     

Trypanosome cyclic nucleotide phosphodiesterase 2B binds cAMP through its GAF-A domain

Trypanosoma brucei, the causative agent of sleeping sickness in humans and livestock, expresses at least three cAMP-specific class I phosphodiesterases (PDEs), all of which are essential for survival of the parasite. These PDEs have either one or two N-terminal GAF domains, which in other proteins function as signaling domains. However, neither the functional roles nor ligands for these domains in trypanosome PDEs are known. The present study shows that TbPDE2B, which contains two tandem GAF domains, binds cAMP with high affinity through its GAF-A domain. A purified recombinant N terminus + GAF-A domain binds cAMP with an affinity (Ki) of approximately 16 nM. It also binds cGMP but with a 15-fold lower affinity of approximately 275 nM. The TbPDE2B holoenzyme has a somewhat lower affinity (approximately 55 nM) for cAMP but a greatly lower affinity (approximately 10 microM) for cGMP. This suggests that both the selectivity and affinity for a ligand can be determined not only by the nature of the binding domain but also by the adjacent domains. Additionally, binding of cAMP to the holoenzyme showed positive cooperativity, with a Hill coefficient value of 1.75. However, binding of cGMP to the holoenzyme did not show any cooperativity, suggesting differences in the conformational changes caused by binding of these two cyclic nucleotides with the protein. Point mutation of a key predicted binding site residue (T317A) resulted in a complete loss of high affinity cAMP binding. This mutation increased the apparent Km of the mutant enzyme for substrate without altering the Vmax. A truncated catalytic domain construct of TbPDE2B also exhibited an increased Km, strongly suggesting that cAMP binding to the GAF-A domain can regulate TbPDE2B by allowing the full activity of the enzyme to be expressed. These properties of the GAF-A domain of TbPDE2B thus suggest that it could be a new target for anti-trypanosomal drugs.     

Adenylyl cyclase Rv0386 from Mycobacterium tuberculosis H37Rv uses a novel mode for substrate selection

Class III adenylyl cyclases usually possess six highly conserved catalytic residues. Deviations in these canonical amino acids are observed in several putative adenylyl cyclase genes as apparent in several bacterial genomes. This suggests that a variety of catalytic mechanisms may actually exist. The gene Rv0386 from Mycobacterium tuberculosis codes for an adenylyl cyclase catalytic domain fused to an AAA-ATPase and a helix-turn-helix DNA-binding domain. In Rv0386, the standard substrate, adenine-defining lysine-aspartate couple is replaced by glutamine-asparagine. The recombinant adenylyl cyclase domain was active with a V(max) of 8 nmol cAMP.mg(-1).min(-1). Unusual for adenylyl cyclases, Rv0386 displayed 20% guanylyl cyclase side-activity with GTP as a substrate. Mutation of the glutamine-asparagine pair either to alanine residues or to the canonical lysine-aspartate consensus abolished activity. This argues for a novel mechanism of substrate selection which depends on two non-canonical residues. Data from individual and coordinated point mutations suggest a model for purine definition based on an amide switch related to that previously identified in cyclic nucleotide phosphodiesterases.     

Spatial expression patterns of genes involved in cyclic AMP responses in Dictyostelium discoideum development

The spatial expression patterns of genes involved in cyclic adenosine monophosphate (cAMP) responses during morphogenesis in Dictyostelium discoideum were analyzed by in situ hybridization. Genes encoding adenylyl cyclase A (ACA), cAMP receptor 1, G-protein alpha2 and beta subunits, cytosolic activator of ACA (CRAC and Aimless), catalytic subunit of protein kinase A (PKA-C) and cAMP phosphodiesterases (PDE and REG-A) were preferentially expressed in the anterior prestalk (tip) region of slugs, which acts as an organizing center. MAP kinase ERK2 (extracellular signal-regulated kinase-2) mRNA, however, was enriched in the posterior prespore region. At the culmination stage, the expression of ACA, CRAC and PKA-C mRNA increased in prespore cells in contrast with the previous stage. However, no alteration in the site of expression was observed for the other mRNA analyzed. Based on these findings, two and four classes of expression patterns were catalogued for these genes during the slug and culmination stages, respectively. Promoter analyses of genes in particular classes should enhance understanding of the regulation of dynamic and coordinated gene expression during morphogenesis.     

Adenylyl cyclase Rv1264 from Mycobacterium tuberculosis has an autoinhibitory N-terminal domain

Mycobacterium tuberculosis contains 15 class III adenylyl cyclase genes. The gene Rv1264 is predicted to be composed of two distinct protein modules. The C terminus seems to code for a catalytic domain belonging to a subfamily of adenylyl cyclase isozymes mostly found in Gram-positive bacteria. The expressed protein was shown to function as a homodimeric adenylyl cyclase (1 micromol of cAMP x mg(-1) x min(-1)). In analogy to the structure of the mammalian adenylyl cyclase catalyst, six amino acids were targeted by point mutations and found to be essential for catalysis. The N-terminal region represents a novel protein domain, the occurrence of which is restricted to several adenylyl cyclases present in Gram-positive bacteria. The purified full-length enzyme was 300-fold less active than the catalytic domain alone. Thus, the N-terminal domain appeared to be autoinhibitory. The N-terminal domain contains three prominent polar amino acid residues (Asp(107), Arg(132), and Arg(191)) that are invariant in all seven sequences of this domain currently available. Mutation of Asp(107) to Ala relaxed the inhibition and resulted in a 6-fold increase in activity of the Rv1264 holoenzyme, thus supporting the role of this domain as a potential novel regulator of adenylyl cyclase activity.     

A MAP kinase necessary for receptor-mediated activation of adenylyl cyclase in Dictyostelium

Analysis of a developmental mutant in Dictyostelium discoideum which is unable to initiate morphogenesis has shown that a protein kinase of the MAP kinase/ERK family affects relay of the cAMP chemotactic signal and cell differentiation. Strains in which the locus encoding ERK2 is disrupted respond to a pulse of cAMP by synthesizing cGMP normally but show little synthesis of cAMP. Since mutant cells lacking ERK2 contain normal levels of both the cytosolic regulator of adenylyl cyclase (CRAC) and manganese-activatable adenylyl cyclase, it appears that this kinase is important for receptor-mediated activation of adenylyl cyclase.     

The SH3 domain of the S. cerevisiae Cdc25p binds adenylyl cyclase and facilitates Ras regulation of cAMP signalling

Cdc25 and Ras are two proteins required for cAMP signalling in the budding yeast Saccharomyces cerevisiae. Cdc25 is the guanine nucleotide exchange protein that activates Ras. Ras, in turn, activates adenylyl cyclase. Cdc25 has a Src homology 3 (SH3) domain near the N-terminus and a catalytic domain in the C-terminal region. We find that a point mutation in the SH3 domain attenuates cAMP signalling in response to glucose feeding. Furthermore, we demonstrate, by using recombinant adenylyl cyclase and Cdc25, that the SH3 domain of Cdc25 can bind directly to adenylyl cyclase. Binding was specific, because the SH3 domain of Abp1p (actin-binding protein 1), which binds the 70,000 Mr subunit of adenylyl cyclase, CAP/Srv2, failed to bind adenylyl cyclase. A binding site for Cdc25-SH3 localised to the C-terminal catalytic region of adenylyl cyclase. Finally, pre-incubation with Ras enhanced the SH3-bound adenylyl cyclase activity. These studies suggest that a direct interaction between Cdc25 and adenylyl cyclase promotes efficient assembly of the adenylyl cyclase complex.     

Identification of RGS2 and type V adenylyl cyclase interaction sites

The production of cAMP is controlled on many levels, notably at the level of cAMP synthesis by the enzyme adenylyl cyclase. We have recently identified a new regulator of adenylyl cyclase activity, RGS2, which decreases cAMP accumulation when overexpressed in HEK293 cells and inhibits the in vitro activity of types III, V, and VI adenylyl cyclase. In addition, RGS2 blocking antibodies lead to elevated cAMP levels in olfactory neurons. Here we examine the nature of the interaction between RGS2 and type V adenylyl cyclase. In HEK293 cells expressing type V adenylyl cyclase, RGS2 inhibited Galpha(s)-Q227L- or beta(2)-adrenergic receptor-stimulated cAMP accumulation. Deletion of the N-terminal 19 amino acids of RGS2 abolished its ability to inhibit cAMP accumulation and to bind adenylyl cyclase. Further mutational analysis indicated that neither the C terminus, RGS GAP activity, nor the RGS box domain is required for inhibition of adenylyl cyclase. Alanine scanning of the N-terminal amino acids of RGS2 identified three residues responsible for the inhibitory function of RGS2. Furthermore, we show that RGS2 interacts directly with the C(1) but not the C(2) domain of type V adenylyl cyclase and that the inhibition by RGS2 is independent of inhibition by Galpha(i). These results provide clear evidence for functional effects of RGS2 on adenylyl cyclase activity that adds a new dimension to an intricate signaling network.     

The regulatory subunit of a cGMP-regulated protein kinase A of Trypanosoma brucei.

This study reports the identification and characterization of the regulatory subunit, TbRSU, of protein kinase A of the parasitic protozoon Trypanosoma brucei. TbRSU is coded for by a single copy gene. The protein contains an unusually long N-terminal domain, the pseudosubstrate site involved in binding and inactivation of the catalytic subunit, and two C-terminally located, closely spaced cyclic nucleotide binding domains. Immunoprecipitation of TbRSU coprecipitates a protein kinase activity with the characteristics of protein kinase A: it phosphorylates a protein kinase specific substrate, and it is strongly inhibited by a synthetic protein kinase inhibitor peptide. Unexpectedly, this kinase activity could not be stimulated by cAMP, but by cGMP only. Binding studies with recombinant cyclic nucleotide binding domains of TbRSU confirmed that both domains bind cGMP with Kd values in the lower micromolar range, and that up to a 100-fold excess of cAMP does not compete with cGMP binding.     

Protein kinase C modulates effects of prostanoids on cyclic adenosine monophosphate in guinea pig chief cells

In the course of examining the role of protein kinase C in signal transduction in dispersed chief cells from guinea pig stomach, we observed that phorbol esters inhibit prostaglandin (PG)-stimulated increases in cyclic adenosine monophosphate (cAMP). Phorbol 12-myristate 13-acetate (PMA), an activator of protein kinase C, decreased maximal levels of PGE2-stimulated cAMP by 40%. This dose-dependent effect was observed within 30 sec and was maximal by 1 min of incubation at 37 degrees C. Phorbols that do not activate protein kinase C did not have this effect. Adding H7, a protein kinase C inhibitor, abolished the inhibitory effects of PMA, indicating that these effects are not caused by activation of cyclic nucleotide phosphodiesterases. PMA did not alter the increase in cellular cAMP caused by cholera toxin, forskolin, secretin, or vasoactive intestinal peptide. Hence the site of these prostanoid-specific actions of protein kinase C does not appear to be stimulatory or inhibitory guanine nucleotide binding proteins or the catalytic component of the adenylyl cyclase system. In dispersed chief cells, activation of protein kinase C may inhibit prostanoid-induced stimulation of the adenylyl cyclase system by a direct effect on prostaglandin receptors.     

Regulation of nuclear PKA revealed by spatiotemporal manipulation of cyclic AMP

Understanding how specific cyclic AMP (cAMP) signals are organized and relayed to their effectors in different compartments of the cell to achieve functional specificity requires molecular tools that allow precise manipulation of cAMP in these compartments. Here we characterize a new method using bicarbonate-activatable and genetically targetable soluble adenylyl cyclase to control the location, kinetics and magnitude of the cAMP signal. Using this live-cell cAMP manipulation in conjunction with fluorescence imaging and mechanistic modeling, we uncovered the activation of a resident pool of protein kinase A (PKA) holoenzyme in the nuclei of HEK-293 cells, modifying the existing dogma of cAMP-PKA signaling in the nucleus. Furthermore, we show that phosphodiesterases and A-kinase anchoring proteins (AKAPs) are critical in shaping nuclear PKA responses. Collectively, our data suggest a new model in which AKAP-localized phosphodiesterases tune an activation threshold for nuclear PKA holoenzyme, thereby converting spatially distinct second messenger signals to temporally controlled nuclear kinase activity.     

Adenylyl cyclases from Plasmodium, Paramecium and Tetrahymena are novel ion channel/enzyme fusion proteins

In Paramecium, cAMP formation is stimulated by a potassium conductance, which is an intrinsic property of the adenylyl cyclase. We cloned a full-length cDNA and several gDNA fragments from Paramecium and Tetrahymena coding for adenylyl cyclases with a novel domain composition. A putative N-terminal ion channel domain contains a canonical S4 voltage-sensor and a canonical potassium pore-loop located C-terminally after the last transmembrane span on the cytoplasmic side. The adenylyl cyclase catalyst is C-terminally located. DNA microinjection of a green fluorescent protein (GFP)-tagged construct into the macronucleus of Paramecium resulted in ciliary localization of the expressed protein. An identical gene coding for an ion-channel adenylyl cyclase was cloned from the malaria parasite Plasmodium falciparum. Expression of the catalytic domain of the latter in Sf9 cells yielded an active homodimeric adenylyl cyclase. The occurrence of this highly unique subtype of adenylyl cyclase appears to be restricted to ciliates and apicomplexa.     

Requirements for the adenylyl cyclases in the development of Dictyostelium

It has been suggested that all intracellular signaling by cAMP during development of Dictyostelium is mediated by the cAMP-dependent protein kinase, PKA, since cells carrying null mutations in the acaA gene that encodes adenylyl cyclase can develop so as to form fruiting bodies under some conditions if PKA is made constitutive by overexpressing the catalytic subunit. However, a second adenylyl cyclase encoded by acrA has recently been found that functions in a cell autonomous fashion during late development. We have found that expression of a modified acaA gene rescues acrA- mutant cells indicating that the only role played by ACR is to produce cAMP. To determine whether cells lacking both adenylyl cyclase genes can develop when PKA is constitutive we disrupted acrA in a acaA- PKA-C(over) strain. When developed at high cell densities, acrA- acaA- PKA-C(over) cells form mounds, express cell type-specific genes at reduced levels and secrete cellulose coats but do not form fruiting bodies or significant numbers of viable spores. Thus, it appears that synthesis of cAMP is required for spore differentiation in Dictyostelium even if PKA activity is high.