Heme b inhibits class III adenylyl cyclases.

Acidic lipid extracts from mouse liver, kidney, heart, brain, and lung inhibited human pseudoheterodimeric adenylyl cyclases (hACs) expressed in HEK293 cells. Using an acidic lipid extract from bovine lung, a combined MS- and bioassay-guided fractionation identified heme b as inhibitor of membrane-bound ACs. IC50 concentrations were 8-12 µM for the hAC isoforms. Hemopexin and bacterial hemophore attenuated heme b inhibition of hAC5. Structurally related compounds, such as hematin, protoporphyrin IX, and biliverdin, were significantly less effective. Monomeric bacterial class III ACs (mycobacterial ACs Rv1625c; Rv3645; Rv1264; cyanobacterial AC CyaG) were inhibited by heme b with similar efficiency. Surprisingly, structurally related chlorophyll a similarly inhibited hAC5. Heme b inhibited isoproterenol-stimulated cAMP accumulation in HEK293 cells. Using cortical membranes from mouse brain hemin efficiently and reversibly inhibited basal and Gsα-stimulated AC activity. The physiological relevance of heme b inhibition of the cAMP generating system in certain pathologies is discussed.

Distinct glycerophospholipids potentiate Gsα-activated adenylyl cyclase activity.

Nine mammalian adenylyl cyclases (AC) are pseudoheterodimers with two hexahelical membrane domains, which are isoform-specifically conserved. Previously we proposed that these membrane domains are orphan receptors (https://doi.org/10.7554/eLife.13098; https://doi.org/10.1016/j.cellsig.2020.109538). Lipids extracted from fetal bovine serum at pH 1 inhibited several mAC activities. Guided by a lipidomic analysis we tested glycerophospholipids as potential ligands. Contrary to expectations we surprisingly discovered that 1-stearoyl-2-docosahexaenoyl-phosphatidic acid (SDPA) potentiated Gsα-activated activity of human AC isoform 3 seven-fold. The specificity of fatty acyl esters at glycerol positions 1 and 2 was rather stringent. 1-Stearoyl-2-docosahexaenoyl-phosphatidylserine and 1-stearoyl-2-docosahexaenoyl-phosphatidylethanolamine significantly potentiated several Gsα-activated mAC isoforms to different extents. SDPA appears not interact with forskolin activation of AC isoform 3. SDPA enhanced Gsα-activated AC activities in membranes from mouse brain cortex. The action of SDPA was reversible. Unexpectedly, SDPA did not affect cAMP generation in HEK293 cells stimulated by isoproterenol, PGE2 and adenosine, virtually excluding a role as an extracellular ligand and, instead, suggesting an intracellular role. In summary, we discovered a new dimension of intracellular AC regulation by chemically defined glycerophospholipids.

Characterization of a novel signal transducer element intrinsic to class IIIa/b adenylate cyclases and guanylate cyclases.

Adenylate cyclases (ACs) are signaling proteins that produce the second messenger cAMP. Class III ACs comprise four groups (class IIIa-d) of which class IIIa and IIIb ACs have been identified in bacteria and eukaryotes. Many class IIIa ACs are anchored to membranes via hexahelical domains. In eukaryotic ACs, membrane anchors are well conserved, suggesting that this region possesses important functional characteristics that are as yet unknown. To address this question, we replaced the hexahelical membrane anchor of the mycobacterial AC Rv1625c with the hexahelical quorum-sensing receptor from Legionella, LqsS. Using this chimera, we identified a novel 19-amino-acid cyclase transducer element (CTE) located N-terminally to the catalytic domain that links receptor stimulation to effector activation. Coupling of the receptor to the AC was possible at several positions distal to the membrane exit, resulting in stimulatory or inhibitory responses to the ligand Legionella autoinducer-1. In contrast, on the AC effector side functional coupling was only successful when starting with the CTE. Bioinformatics approaches established that distinct CTEs are widely present in class IIIa and IIIb ACs and in vertebrate guanylate cyclases. The data suggest that membrane-delimited receiver domains transduce regulatory signals to the downstream catalytic domains in an engineered AC model system. This may suggest a previously unknown mechanism for cellular cAMP regulation.

Biochemical characterization of the tandem HAMP domain from Natronomonas pharaonis as an intraprotein signal transducer.

Available structures of HAMP domains suggest rotation as one potential mechanism in intraprotein signal transduction. It has been proposed that in poly-HAMP modules the signal sign is inverted with each additional HAMP. We examined signal transduction through the HAMP tandem domain from the phototaxis transducer of the halophilic archaeon Natronomonas pharaonis in membrane-bound chimeras consisting of the Escherichia coli chemotaxis receptor for serine, Tsr, as an input and the mycobacterial adenylyl cyclase Rv3645 as an output domain, i.e. the basic chimera was 'Tsr-NpHAMP tandem-Rv3645 cyclase'. Neither of the NpHAMP units alone nor the NpHAMP tandem transduced a serine signal. After five targeted point mutations in the first α-helix of NpHAMP1 , the non-functional NpHAMP modules combined into a functional HAMP tandem. 1 mm serine significantly inhibited cyclase activity (-35%; IC50  = 30 µm) in disagreement with the structure-based predictions. Surprisingly, replacement of NpAS11 in the tandem by the respective AS1 from HAMPT sr resulted in signal inversion, i.e. serine activated cyclase (+129%; EC50  = 10 µm). Examination of 48 mutants of AS11 in the HAMP tandem including two residues of a putative N-terminal control cable identified five residues in NpAS11 which probably define different ground states of the output domain and thus affect the sign of signal output. The data question the predicted HAMP rotation as the predominant mechanism of intraprotein signal transduction and point to as yet unrecognized conformational motions of HAMP domains in intraprotein signaling.

The S-helix determines the signal in a Tsr receptor/adenylyl cyclase reporter.

A signaling or S-helix has been identified as a conserved, up to 50-residue-long segment in diverse sensory proteins. It is present in all major bacterial lineages and in euryarchea and eukaryotes. A bioinformatic analysis shows that it connects upstream receiver and downstream output domains, e.g. in histidine kinases and bacterial adenylyl cyclases. The S-helix is modeled as a two-helical parallel coiled coil. It is predicted to prevent constitutive activation of the downstream signaling domains in the absence of ligand-binding. We identified an S-helix of about 25 residues in the adenylyl cyclase CyaG from Arthrospira maxima. Deletion of the 25 residue segment connecting the HAMP and catalytic domains in a chimera with the Escherichia coli Tsr receptor changed the response to serine from inhibition to stimulation. Further examination showed that a deletion of one to three heptads plus a presumed stutter, i.e. 1, 2, or 3 × 7 + 4 amino acids, is required and sufficient for signal reversion. It was not necessary that the deletions be continuous, as removal of separated heptads and presumed stutters also resulted in signal reversion. Furthermore, insertion of the above segments between the HAMP and cyclase catalytic domains similarly resulted in signal reversion. This indicates that the S-helix is an independent, segmented module capable to reverse the receptor signal. Because the S-helix is present in all kingdoms of life, e.g. in human retinal guanylyl cyclase, our findings may be significant for many sensory systems.

HAMP domain-mediated signal transduction probed with a mycobacterial adenylyl cyclase as a reporter.

HAMP domains, ∼55 amino acid motifs first identified in histidine kinases, adenylyl cyclases, methyl-accepting chemotaxis proteins, and phosphatases, operate as signal mediators in two-component signal transduction proteins. A bioinformatics study identified a coevolving signal-accepting network of 10 amino acids in membrane-delimited HAMP proteins. To probe the functionality of this network we used a HAMP containing mycobacterial adenylyl cyclase, Rv3645, as a reporter enzyme in which the membrane anchor was substituted by the Escherichia coli chemotaxis receptor for serine (Tsr receptor) and the HAMP domain alternately with that from the protein Af1503 of the archaeon Archaeoglobus fulgidus or the Tsr receptor. In a construct with the Tsr-HAMP, cyclase activity was inhibited by serine, whereas in a construct with the HAMP domain from A. fulgidus, enzyme activity was not responsive to serine. Amino acids of the signal-accepting network were mutually swapped between both HAMP domains, and serine signaling was examined. The data biochemically tentatively established the functionality of the signal-accepting network. Based on a two-state gearbox model of rotation in HAMP domain-mediated signal propagation, we characterized the interaction between permanent and transient core residues in a coiled coil HAMP structure. The data are compatible with HAMP rotation in signal propagation but do not exclude alternative models for HAMP signaling. Finally, we present data indicating that the connector, which links the α-helices of HAMP domains, plays an important structural role in HAMP function.

Intramolecular signaling in tandem-GAF domains from PDE5 and PDE10 studied with a cyanobacterial adenylyl cyclase reporter.

The dimeric mammalian phosphodiesterases (PDEs) are regulated by N-terminal domains. In PDE5, the GAF-A subdomain of a GAF-tandem (GAF-A and -B) binds the activator cGMP and in PDE10 GAF-B binds cAMP. GAF-tandem chimeras of PDE5 and 10 in which the 36 aa linker helix between GAF-A and -B was swapped lost allosteric regulation of a reporter adenylyl cyclase. In 16 consecutive constructs we substituted the PDE10 linker with that from PDE5. An initial stretch of 10 amino acids coded for isoform specificity. A C240Y substitution uncoupled cyclase activity from regulation, whereas C240F, L or G did not. The C240Y substitution increased basal activity to stimulated levels. Notably, over the next 12 substitutions basal cyclase activity decreased linearly. Further targeted substitutions were based on homology modeling using the PDE2 structure. No combination of substitutions within the initial 10 linker residues caused loss of regulation. The full 10 aa stretch was required. Modeling indicated a potential interaction of the linker with a loop from GAF-A. To interrupt H-bonding a glycine substitution of the loop segment was generated. Despite reduction of basal activity, loss of regulation was maintained. Possibly, the orientation of the linker helix is determined by formation of the dimer at the initial linker segment. Downstream deflections of the linker helix may have caused loss of regulation.

Transmembrane signaling in chimeras of the Escherichia coli aspartate and serine chemotaxis receptors and bacterial class III adenylyl cyclases.

The Escherichia coli chemoreceptors for serine (Tsr) and aspartate (Tar) and several bacterial class III adenylyl cyclases (ACs) share a common molecular architecture; that is, a membrane anchor that is linked via a cytoplasmic HAMP domain to a C-terminal signal output unit. Functionality of both proteins requires homodimerization. The chemotaxis receptors are well characterized, whereas the typical hexahelical membrane anchor (6TM) of class III ACs, suggested to operate as a channel or transporter, has no known function beyond a membrane anchor. We joined the intramolecular networks of Tsr or Tar and two bacterial ACs, Rv3645 from Mycobacterium tuberculosis and CyaG from Arthrospira platensis, across their signal transmission sites, connecting the chemotaxis receptors via different HAMP domains to the catalytic AC domains. AC activity in the chimeras was inhibited by micromolar concentrations of l-serine or l-aspartate in vitro and in vivo. Single point mutations known to abolish ligand binding in Tar (R69E or T154I) or Tsr (R69E or T156K) abrogated AC regulation. Co-expression of mutant pairs, which functionally complement each other, restored regulation in vitro and in vivo. Taken together, these studies demonstrate chemotaxis receptor-mediated regulation of chimeric bacterial ACs and connect chemical sensing and AC regulation.

Polyphosphates from Mycobacterium bovis--potent inhibitors of class III adenylate cyclases.

cAMP generation in bacteria is often stimulated by sudden, but lasting, changes in extracellular conditions, whereas intracellular cAMP concentrations quickly settle at new levels. As bacteria lack G-proteins, it is unknown how bacterial adenylate cyclase (AC) activities are modulated. Mycobacterium tuberculosis has 15 class III AC genes; therefore, we examined whether mycobacteria contain a factor that may regulate AC activities. We identified mycobacterial polyphosphates with a mean chain length of 72 residues as highly potent inhibitors of dimeric class IIIa, class IIIb and class IIIc ACs from M. tuberculosis and other bacteria. The identity of the inhibitor was established by phosphatase degradation, 31P-NMR, acid or base hydrolysis, PAGE and comparisons with commercial standards, and functional substitution by several polyphosphates. The data indicate that each AC dimer occupies 8-15 phosphate residues on a polyphosphate strand. Other polyionic polymers such as polyglutamate, polylysine and hyaluronic acid do not affect cyclase activity. Notably, the structurally unrelated class I AC Cya from Escherichia coli is unaffected. Bacterial polyphosphate metabolism is generally viewed in the context of stress-related regulatory networks. Thus, regulation of bacterial class III ACs by polyphosphates could be a component of the bacterial stress response.

Functional chimeras of the phosphodiesterase 5 and 10 tandem GAF domains.

The tandem GAF domain of hPDE10A uses cAMP as an allosteric ligand (Gross-Langenhoff, M., Hofbauer, K., Weber, J., Schultz, A., and Schultz, J. E. (2006) J. Biol. Chem. 281, 2841-2846). We used a two-pronged approach to study how discrimination of ligand is achieved in human (h)PDE10A and how domain selection in the phosphodiesterase GAF tandems is determined. First, we examined which functional groups of cAMP are responsible for purine ring discrimination. Changes at the C-6 ring position (removal of the amino group; chloride substitution) and at the N-1 ring position reduced stimulation efficacy by 80%, i.e. marking those positions as decisive for nucleotide discrimination. Second, we generated a GAF tandem chimera that consisted of the cGMP-binding GAF-A unit from hPDE5A1, which signals through cGMP in PDE5, and the GAF-B from hPDE10A1, which signals through cAMP in PDE10. Stimulation of the reporter enzyme exclusively was through the GAF-B domain of hPDE10A1 (EC(50) = 7 microm cAMP) as shown by respective point mutations. The PDE5 GAF-A domain in the chimera did not signal, and its function was reduced to a strictly structural role. Signaling was independent of the origin of the N terminus. Generating 10 additional PDE5/10 tandem GAF chimeras surprisingly demonstrated that the length-conserved linker in GAF tandems between GAF-A and GAF-B played an unforeseen decisive role in intramolecular signaling. Swapping the linker sections between PDE5 and PDE10 GAF tandem domains abrogated signaling completely pointing to specific domain interactions within GAF tandems, which are not visible in the available crystal structures with bound ligands.

The properties of phosphodiesterase 11A4 GAF domains are regulated by modifications in its N-terminal domain.

The tandem GAF domain of human phosphodiesterase 11A4 (hPDE11A4) requires 72 microm cGMP for half-maximal effective concentration (EC(50)) of a cyanobacterial adenylyl cyclase used as a reporter enzyme. Here we examine whether modifications in the N-terminus of PDE11A4 affect cGMP signalling. The N-terminus has two phosphorylation sites for cyclic nucleotide monophosphate-dependent protein kinases (Ser117, Ser168). Phosphorylation of both by cAMP-dependent protein kinase decreased the EC(50) value for cGMP from 72 to 23 microm. Phosphomimetic point mutations (S117D/S167D), which project complete phosphorylation, lowered the EC(50) value to 16 microm. Structural and sequence data indicate that 196 amino acids precede the start of the GAF domain in hPDE11A4. Removal of 197 amino acids yielded unregulated cyclase activity, whereas truncation by 196 amino acids resulted in a cGMP-regulated protein with a cGMP EC(50) value of 7.6 microm. Truncation by 176 amino acids was required for cGMP EC(50) values to decrease to below 10 microm; a construct truncated by 168 amino acids had an EC(50) value of 224 microm. The decrease in EC(50) values was accompanied by a sixfold increase in basal activity; the extent of cGMP stimulation remained unaffected, however. We conclude that N-terminal modifications strongly affect cGMP regulation of hPDE11A4.

The structure of the regulatory domain of the adenylyl cyclase Rv1264 from Mycobacterium tuberculosis with bound oleic acid.

The universal secondary messenger cAMP is produced by adenylyl cyclases (ACs). Most bacterial and all eukaryotic ACs belong to class III of six divergent classes. A class III characteristic is formation of the catalytic pocket at a dimer interface and the presence of additional regulatory domains. Mycobacterium tuberculosis possesses 15 class III ACs, including Rv1264, which is activated at acidic pH due to pH-dependent structural transitions of the Rv1264 dimer. It has been shown by X-ray crystallography that the N-terminal regulatory and C-terminal catalytic domains of Rv1264 interact in completely different ways in the active and inhibited states. Here, we report an in-depth structural and functional analysis of the regulatory domain of Rv1264. The 1.6 A resolution crystal structure shows the protein in a tight, disk-shaped dimer, formed around a helical bundle, and involving a protein chain crossover. To understand pH regulation, we determined structures at acidic and basic pH values and employed structure-based mutagenesis in the holoenzyme to elucidate regulation using an AC activity assay. It has been shown that regulatory and catalytic domains must be linked in a single protein chain. The new studies demonstrate that the length of the linker segment is decisive for regulation. Several amino acids on the surface of the regulatory domain, when exchanged, altered the pH-dependence of AC activity. However, these residues are not conserved amongst a number of related ACs. The closely related mycobacterial Rv2212, but not Rv1264, is strongly activated by the addition of fatty acids. The structure resolved the presence of a deeply embedded fatty acid, characterised as oleic acid by mass spectrometry, which may serve as a hinge. From these data, we conclude that the regulatory domain is a structural scaffold used for distinct regulatory purposes.

Changes in purine specificity in tandem GAF chimeras from cyanobacterial cyaB1 adenylate cyclase and rat phosphodiesterase 2.

The C-terminal catalytic domains of the 11 mammalian phosphodiesterase families (PDEs) are important drug targets. Five of the 11 PDE families contain less well-characterized N-terminal GAF domains. cGMP is the ligand for the GAF domains in PDEs 2, 5, 6 and 11, and cAMP is the ligand for PDE10. Structurally related tandem GAF domains signalling via cAMP are present in the cyanobacterial adenylate cyclases cyaB1 and cyaB2. Because current high-resolution crystal structures of the tandem GAF domains of PDE2 and cyaB2 do not reveal how cNMP specificity is encoded, we generated chimeras between the tandem GAF domains of cyaB1 and PDE2. Both bind the ligand in the GAF B subdomains. Segmental replacements in the highly divergent beta1-beta3 region of the GAF B subdomain of cyaB1 by the corresponding PDE2 regions switched signalling from cAMP to cGMP. Using 10 chimeric constructs, we demonstrated that, for this switch in purine specificity, only 11% of the sequence of the cyanobacterial GAF B needs to be replaced by PDE2 sequences. We were unable, however, to switch the purine specificity of the PDE2 tandem GAF domain from cGMP to cAMP in reverse constructs, i.e. by replacement of PDE2 segments with those from the cyaB1 GAF tandem domain. The data provide a novel view on the structure-function relationships underlying the purine specificity of cNMP-binding GAF domains and indicate that, as potential drug targets, they must be characterized structurally and biochemically one by one.

The HAMP domain structure implies helix rotation in transmembrane signaling.

HAMP domains connect extracellular sensory with intracellular signaling domains in over 7500 proteins, including histidine kinases, adenylyl cyclases, chemotaxis receptors, and phosphatases. The solution structure of an archaeal HAMP domain shows a homodimeric, four-helical, parallel coiled coil with unusual interhelical packing, related to the canonical packing by rotation of the helices. This suggests a model for the mechanism of signal transduction, in which HAMP alternates between the observed conformation and a canonical coiled coil. We explored this mechanism in vitro and in vivo using HAMP domain fusions with a mycobacterial adenylyl cyclase and an E. coli chemotaxis receptor. Structural and functional studies show that the equilibrium between the two forms is dependent on the side-chain size of residue 291, which is alanine in the wild-type protein.

Characterization of the tandem GAF domain of human phosphodiesterase 5 using a cyanobacterial adenylyl cyclase as a reporter enzyme.

We analyzed cGMP signaling by the human phosphodiesterase 5 (hPDE5) tandem GAF domain based on a functional activation assay. The C-terminal catalytic domain of the cyanobacterial adenylyl cyclase (AC) cyaB1 was used as a reporter enzyme. We demonstrate functional coupling between the hPDE5 GAF ensemble and the AC resulting in a chimera stimulated 10-fold by cGMP. The hPDE5 GAF domain has an inhibitory effect on AC activity, which is released upon cGMP activation. Removal of 109 amino acids from the N terminus resulted in partial disengagement of the GAF domain and AC, i.e. in a 10-fold increase in basal activity, and affected cGMP affinity. The Ser-102 phosphorylation site of hPDE5 increased cGMP affinity, as shown by a 5-fold lower K(D) for cGMP in a S102D mutant, which mimicked complete modification. The function of the NKFDE motif, which is a signature of all GAF domains with known cyclic nucleotide binding capacity, was elucidated by targeted mutations. Data with either single and double mutants in either GAF A or GAF B or a quadruple mutant affecting both subdomains simultaneously indicated that it is impossible to functionally assign cGMP binding and intramolecular signaling to either GAF A or B of hPDE5. Both subdomains are structurally and functionally interdependent and act in concert in regulating cycaB1 AC and, most likely, also hPDE5.

cAMP is a ligand for the tandem GAF domain of human phosphodiesterase 10 and cGMP for the tandem GAF domain of phosphodiesterase 11.

N-terminal tandem GAF domains are present in 5 out of 11 mammalian phosphodiesterase (PDE) families. The ligand for the GAF domains of PDEs 2, 5, and 6 is cGMP, whereas those for PDEs 10 and 11 remained enigmatic for years. Here we used the cyanobacterial cyaB1 adenylyl cyclase, which has an N-terminal tandem GAF domain closely related to those of the mammalian PDEs, as an assay system to identify the ligands for the human PDEs 10 and 11 GAF domains. We report that a chimera between the PDE10 GAF domain and the cyanobacterial cyclase was 9-fold stimulated by cAMP (EC50= 19.8 microm), whereas cGMP had only low activity. cAMP increased Vmax in a non-cooperative manner and did not affect the Km for ATP of 27 microm. In an analogous chimeric construct with the tandem GAF domain of human PDE11A4, cGMP was identified as an allosteric activator (EC50 = 72.5 microm) that increased Vmax of the cyclase non-cooperatively 4-fold. GAF-B of PDE10 and GAF-A of PDE11A4 contain an invariant NKFDE motif present in all mammalian PDE GAF ensembles. We mutated the aspartates within this motif in both regions and found that intramolecular signaling was considerably reduced or abolished. This was in line with all data concerning GAF domains with an NKFDE motif as far as they have been tested. The data appeared to define those GAF domains as a distinct subclass within the >3100 annotated GAF domains for which we propose a tentative classification scheme.

Interaction of Rv1625c, a mycobacterial class IIIa adenylyl cyclase, with a mammalian congener.

The adenylyl cyclase Rv1625c from Mycobacterium tuberculosis codes for a protein with six transmembrane spans and a catalytic domain, i.e. it corresponds to one half of the pseudoheterodimeric mammalian adenylyl cyclases (ACs). Rv1625c is active as a homodimer. We investigated the role of the Rv1625c membrane domain and demonstrate that it efficiently dimerizes the protein resulting in a 7.5-fold drop in K(m) for ATP. Next, we generated a duplicated Rv1625c AC dimer by a head-to-tail concatenation. This produced an AC with a domain order exactly as the mammalian pseudoheterodimers. It displayed positive cooperativity and a 60% increase of v(max) compared with the Rv1625c monomer. Further, we probed the compatibility of mycobacterial and mammalian membrane domains. The second membrane anchor in the Rv1625c concatamer was replaced with membrane domain I or II of rabbit type V AC. The mycobacterial and either mammalian membrane domains are compatible with each other and both recombinant proteins are active. A M. tuberculosis Rv1625c knockout strain was assayed in a mouse infection model. In vitro growth characteristics and in vivo organ infection and mortality were unaltered in the knockout strain indicating that AC Rv1625c alone is not a virulence factor.

The structure of a pH-sensing mycobacterial adenylyl cyclase holoenzyme.

Class III adenylyl cyclases contain catalytic and regulatory domains, yet structural insight into their interactions is missing. We show that the mycobacterial adenylyl cyclase Rv1264 is rendered a pH sensor by its N-terminal domain. In the structure of the inhibited state, catalytic and regulatory domains share a large interface involving catalytic residues. In the structure of the active state, the two catalytic domains rotate by 55 degrees to form two catalytic sites at their interface. Two alpha helices serve as molecular switches. Mutagenesis is consistent with a regulatory role of the structural transition, and we suggest that the transition is regulated by pH.

Crystal structure of the tandem GAF domains from a cyanobacterial adenylyl cyclase: modes of ligand binding and dimerization.

In several species, GAF domains, which are widely expressed small-molecule-binding domains that regulate enzyme activity, are known to bind cyclic nucleotides. However, the molecular mechanism by which cyclic nucleotide binding affects enzyme activity is not known for any GAF domain. In the cyanobacterium, Anabaena, the cyaB1 and cyaB2 genes encode adenylyl cyclases that are stimulated by binding of cAMP to their N-terminal GAF domains. Replacement of the tandem GAF-A/B domains in cyaB1 with the mammalian phosphodiesterase 2A GAF-A/B tandem domains allows regulation of the chimeric protein by cGMP, suggesting a highly conserved mechanism of activation. Here, we describe the 1.9-A crystal structure of the tandem GAF-A/B domains of cyaB2 with bound cAMP and compare it to the previously reported structure of the PDE2A GAF-A/B. Unexpectedly, the cyaB2 GAF-A/B dimer is antiparallel, unlike the parallel dimer of PDE2A. Moreover, there is clear electron density for cAMP in both GAF-A and -B, whereas in PDE2A, cGMP is found only in GAF-B. Phosphate and ribose group contacts are similar to those in PDE2A. However, the purine-binding pockets appear very different from that in PDE2A GAF-B. Differences in the beta2-beta3 loop suggest that this loop confers much of the ligand specificity in this and perhaps in many other GAF domains. Finally, a conserved asparagine appears to be a new addition to the signature NKFDE motif, and a mechanism for this motif to stabilize the cNMP-binding pocket is proposed.

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.