Squalene-hopene cyclases

Hopanoids and sterols are members of a large group of cyclic triterpenoic compounds that have important functions in many prokaryotic and eukaryotic organisms. They are biochemically synthesized from linear precursors (squalene, 2,3-oxidosqualene) in only one enzymatic step that is catalyzed by squalene-hopene cyclase (SHC) or oxidosqualene cyclase (OSC). SHCs and OSCs are related in amino acid sequences and probably are derived from a common ancestor. The SHC reaction requires the formation of five ring structures, 13 covalent bonds, and nine stereo centers and therefore is one of the most complex one-step enzymatic reactions. We summarize the knowledge of the properties of triterpene cyclases and details of the reaction mechanism of Alicyclobacillus acidocaldarius SHC. Properties of other SHCs are included.     

Inhibition by calcium of mammalian adenylyl cyclases

Ca(2+) regulates mammalian adenylyl cyclases in a type-specific manner. Stimulatory regulation is moderately well understood. By contrast, even the concentration range over which Ca(2+) inhibits adenylyl cyclases AC5 and AC6 is not unambiguously defined; even less so is the mechanism of inhibition. In the present study, we compared the regulation of Ca(2+)-stimulable and Ca(2+)-inhibitable adenylyl cyclases expressed in Sf9 cells with tissues that predominantly express these activities in the mouse brain. Soluble forms of AC5 containing either intact or truncated major cytosolic domains were also examined. All adenylyl cyclases, except AC2 and the soluble forms of AC5, displayed biphasic Ca(2+) responses, suggesting the presence of two Ca(2+) sites of high ( approximately 0.2 microM) and low affinity ( approximately 0.1 mM). With a high affinity, Ca(2+) (i) stimulated AC1 and cerebellar adenylyl cyclases, (ii) inhibited AC6 and striatal adenylyl cyclase, and (iii) was without effect on AC2. With a low affinity, Ca(2+) inhibited all adenylyl cyclases, including AC1, AC2, AC6, and both soluble forms of AC5. The mechanism of both high and low affinity inhibition was revealed to be competition for a stimulatory Mg(2+) site(s). A remarkable selectivity for Ca(2+) was displayed by the high affinity site, with a K(i) value of approximately 0.2 microM, in the face of a 5000-fold excess of Mg(2+). The present results show that high and low affinity inhibition by Ca(2+) can be clearly distinguished and that the inhibition occurs type-specifically in discrete adenylyl cyclases. Distinction between these sites is essential, or quite spurious inferences may be drawn on the nature or location of high affinity binding sites in the Ca(2+)-inhibitable adenylyl cyclases.     

Particulate guanylyl cyclases: multiple mechanisms of activation

Cyclic GMP (cGMP), a key messenger in several signal transduction pathways, is synthesized from GTP by a family of enzymes termed guanylyl cyclases, which are found in two forms: cytosolic (soluble) and membrane-bound (particulate). The past decade has brought significant progress in understanding the molecular mechanisms that underlie the regulation of particulate guanylyl cyclases and new members of their family have been identified. It has become more evident that the basic mechanism of catalysis of guanylyl cyclases is analogous to that recognized in adenylyl cyclases. Here we review the known basic mechanisms that contribute to the regulation of particulate guanylyl cyclases.     

Class III nucleotide cyclases in bacteria and archaebacteria: lineage-specific expansion of adenylyl cyclases and a dearth of guanylyl cyclases

The Class III nucleotide cyclases are found in bacteria, eukaryotes and archaebacteria. Our survey of the bacterial and archaebacterial genome and plasmid sequences identified 193 Class III cyclase genes in only 29 species, of which we predict the majority to be adenylyl cyclases. Interestingly, several putative cyclase genes were found to have non-conserved substrate specifying residues. Ancestors of the eukaryotic C1-C2 domain containing soluble adenylyl cyclases as well as the protist guanylyl cyclases were found in bacteria. Diverse domains were fused to the cyclase domain and phylogenetic analysis indicated that most proteins within a single cluster have similar domain compositions, emphasising the ancient evolutionary origin and versatility of the cyclase domain.     

Plant purine nucleotide cyclases

Cyclic nucleotides (cAMP and cGMP) play an essential role in many important cellular processes in prokaryotic and eukaryotic organisms. They are produced by purine nucleotide cyclases: adenylyl and guanylyl cyclases. They are classified as one of two distinct forms: soluble and bound to membranes. Beside the differences in enzyme localization, the domain structure and regulation of enzymes activity are also diverse. However, all cyclases possess three groups of important residues: substrate specifying residue, metal binding residues and transition state stabilization residues. The natural occurrence of cyclic nucleotides in plants is now established. It was shown that in higher plants cNMPs act as a second messengers in a large number of (patho)physiological responses. However, it is only recently that the first plant enzymes with AC and GC activity of the unique structure have been identified and functionally characterized. In this study a systematic analysis of all the known prokaryotic, fungal and animal cyclases was done and direct evidences for the presence AC and GC in plant cells were shown.     

Dimerization of mammalian adenylate cyclases.

Mammalian adenylate cyclases are predicted to possess complex topologies, comprising two cassettes of six transmembrane-spanning motifs followed by a cytosolic, catalytic ATP-binding domain. Recent studies have begun to provide insights on the tertiary assembly of these proteins; crystallographic analysis has revealed that the two cytosolic domains dimerize to form a catalytic core, while more recent biochemical and cell biological analysis shows that the two transmembrane cassettes also associate to facilitate the functional assembly and trafficking of the enzyme. The older literature had suggested that adenylate cyclases might form higher order aggregates, although the methods used did not necessarily provide convincing evidence of biologically relevant events. In the present study, we have pursued this question by a variety of approaches, including rescue or suppression of function by variously modified molecules, coimmunoprecipitation and fluorescence resonance energy transfer (FRET) analysis between molecules in living cells. The results strongly suggest that adenylate cyclases dimerize (or oligomerize) via their hydrophobic domains. It is speculated that this divalent property may allow adenylate cyclases to participate in multimeric signaling assemblies.     

Guanylyl cyclases in unicellular organisms

Guanylyl cyclases in eukaryotic unicells were biochemically investigated in the ciliates Paramecium and Tetrahymena, in the malaria parasite Plasmodium and in the ameboid Dictyostelium. In ciliates guanylyl cyclase activity is calcium-regulated suggesting a structural kinship to similarly regulated membrane-bound guanylyl cyclases in vertebrates. Yet, cloning of ciliate guanylyl cyclases revealed a novel combination of known modular building blocks. Two cyclase homology domains are inversely arranged in a topology of mammalian adenylyl cyclases, containing two cassettes of six transmembrane spans. In addition the protozoan guanylyl cyclases contain an N-terminal P-type ATPase-like domain. Sequence comparisons indicate a compromised ATPase function. The adopted novel function remains enigmatic to date. The topology of the guanylyl cyclase domain in all protozoans investigated is identical. A recently identified Dictyostelium guanylyl cyclase lacks the N-terminal P-type ATPase domain. The close functional relation of Paramecium guanylyl cyclases to mammalian adenylyl cyclases has been established by heterologous expression, respective point mutations and a series of active mammalian adenylyl cyclase/Paramecium guanylyl cyclase chimeras. The unique structure of protozoan guanylyl cyclases suggests that unexpectedly they do not share a common guanylyl cyclase ancestor with their vertebrate congeners but probably originated from an ancestral mammalian-type adenylyl cyclase.     

A defined subset of adenylyl cyclases is regulated by bicarbonate ion

The molecular basis by which organisms detect and respond to fluctuations in inorganic carbon is not known. The cyaB1 gene of the cyanobacterium Anabaena sp. PCC7120 codes for a multidomain protein with a C-terminal class III adenylyl cyclase catalyst that was specifically stimulated by bicarbonate ion (EC50 9.6 mm). Bicarbonate lowered substrate affinity but increased reaction velocity. A point mutation in the active site (Lys-646) reduced activity by 95% and was refractory to bicarbonate activation. We propose that Lys-646 specifically coordinates bicarbonate in the active site in conjunction with an aspartate to threonine polymorphism (Thr-721) conserved in class III adenylyl cyclases from diverse eukaryotes and prokaryotes. Using recombinant proteins we demonstrated that adenylyl cyclases that contain the active site threonine (cyaB of Stigmatella aurantiaca and Rv1319c of Mycobacterium tuberculosis) are bicarbonate-responsive, whereas adenylyl cyclases with a corresponding aspartate (Rv1264 of Mycobacterium) are bicarbonate-insensitive. Large numbers of class III adenylyl cyclases may therefore be activated by bicarbonate. This represents a novel mechanism by which diverse organisms can detect bicarbonate ion.     

Diterpene cyclases and the nature of the isoprene fold

The structures and mechanism of action of many terpene cyclases are known, but no structures of diterpene cyclases have yet been reported. Here, we propose structural models based on bioinformatics, site‐directed mutagenesis, domain swapping, enzyme inhibition, and spectroscopy that help explain the nature of diterpene cyclase structure, function, and evolution. Bacterial diterpene cyclases contain ～20 α‐helices and the same conserved “QW” and DxDD motifs as in triterpene cyclases, indicating the presence of a βγ barrel structure. Plant diterpene cyclases have a similar catalytic motif and βγ‐domain structure together with a third, α‐domain, forming an αβγ structure, and in H⁺‐initiated cyclases, there is an EDxxD‐like Mg²⁺/diphosphate binding motif located in the γ‐domain. The results support a new view of terpene cyclase structure and function and suggest evolution from ancient (βγ) bacterial triterpene cyclases to (βγ) bacterial and thence to (αβγ) plant diterpene cyclases. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Pulse sequences for detection of NH2···N hydrogen bonds in sheared G⋅A mismatches via remote, non-exchangeable protons

The non-detectability of NH...N hydrogen bonds in nucleic acids due to exchange broadened imino/amino protons has recently been addressed via the use of non-exchangeable protons for detecting internucleotide 2hJ(NN) couplings. In these applications, the appropriate non-exchangeable proton is separated by two bonds from the NH...N bond. In this paper, we extend the scope of this approach to protons which are separated by four bonds from the NH...N moiety. Specifically, we consider the case of the commonly occurring sheared G x A mismatch alignment, in which we use the adenine H2 proton to report on the (A)N6H6(1.2)...N3(G) hydrogen bond, in the presence of undetectable, exchange broadened N6H6(1.2) protons. Two sequences, the 'straight-through' (H6)N6N3H2 and 'out-and-back' H2N6N3 experiments, are presented for observing these correlations in H2O and D2O solution, respectively. The sequences are demonstrated on two uniformly 15N,13C labelled DNA samples: d(G1G2G3T4T5C6A7G8G9)2, containing a G3 x (C6-A7) triad involving a sheared G3 x A7 mismatch, and d(G1G2G3C4A5G6G7T8)4, containing an A5 x (G3 x G6 x G3 x G6) x A5 hexad involving a sheared G3 x A5 mismatch.     

A functional chimera of mammalian guanylyl and adenylyl cyclases

Adenylyl and guanylyl cyclases synthesize second messenger molecules by intramolecular esterification of purine nucleotides, i.e., cAMP from ATP and cGMP from GTP, respectively. Despite their sequence homology, both families of mammalian cyclases show remarkably different regulatory patterns. In an attempt to define the functional domains in adenylyl cyclase responsible for their isotypic-common activation by Galphas or forskolin, dimeric chimeras were constructed from soluble guanylyl cyclase alpha1 subunit and the C-terminal halves of adenylyl cyclases type I, II, or V. The cyclase-hybrid generated cAMP and was inhibited by P-site ligands. The data establish structural equivalence and the ability of functional complement at the catalytic sites in both cyclases. Detailed enzymatic characterization of the chimeric cyclase revealed a crucial role of the N-terminal adenylyl cyclase half for stimulatory actions, and a major importance of the C-terminal part for nucleotide specificity.     

Guanylyl cyclases, a growing family of signal-transducing enzymes.

Guanylyl cyclases, which catalyze the formation of the intracellular signal molecule cyclic GMP from GTP, display structural features similar to other signal-transducing enzymes such as protein tyrosine-kinases and protein tyrosine-phosphatases. So far, three isoforms of mammalian membrane-bound guanylyl cyclases (GC-A, GC-B, GC-C), which are stimulated by either natriuretic peptides (GC-A, GC-B) or by the enterotoxin of Escherichia coli (GC-C), have been identified. These proteins belong to the group of receptor-linked enzymes, with different NH2-terminal extracellular receptor domains coupled to a common intracellular catalytic domain. In contrast to the membrane-bound enzymes, the heme-containing soluble guanylyl cyclase is stimulated by NO and NO-containing compounds and consists of two subunits (alpha 1 and beta 1). Both subunits contain the putative catalytic domain, which is conserved in the membrane-bound guanylyl cyclases and is found twice in adenylyl cyclases. Coexpression of the alpha 1- and beta 1-subunit is required to yield a catalytically active enzyme. Recently, another subunit of soluble guanylyl cyclase was identified and designated beta 2, revealing heterogeneity among the subunits of soluble guanylyl cyclase. Thus, different enzyme subunits may be expressed in a tissue-specific manner, leading to the assembly of various heterodimeric enzyme forms. The implications concerning the physiological regulation of soluble guanylyl cyclase are not known, but different mechanisms of soluble enzyme activation may be due to heterogeneity among the subunits of soluble guanylyl cyclase.     

Invertebrates yield a plethora of atypical guanylyl cyclases

Invertebrate model systems have a long history of generating new insights into neuronal signaling systems. This review focuses on cyclic GMP signaling and describes recent advances in understanding the properties and functions of guanylyl cyclases in invertebrates. The sequencing of three invertebrate genomes has provided a complete catalog of the guanylyl cyclases in C. elegans, Drosophila, and the mosquito Anopheles gambiae. Using this data and that from cloned guanylyl cyclases in Manduca sexta, C. elegans, and Drosophila, plus predictions and models from vertebrate guanylyl cyclases, evidence is presented that there is a much broader array of properties for these enzymes than previously realized. In addition to the classic homodimeric receptor guanylyl cyclases, C. elegans has at least two receptor guanylyl cyclases that are predicted to require heterodimer formation for activity. Soluble guanylyl cyclases are generally recognized as being obligate heterodimers that are activated by nitric oxide (NO). Some of the soluble guanylyl cyclases in C. elegans may heterodimeric, but all appear to be insensitive to NO. The β2 soluble guanylyl cyclase subunit in mammals and similar ones in Manduca and Drosophila are active in the absence of additional subunits and there is evidence that Drosophila and Anopheles also express an additional subunit that enhances this activity.     

Identification of bacterial guanylate cyclases

The ability of bacteria to use cGMP as a second messenger has been controversial for decades. Recently, nucleotide cyclases from Rhodospirillum centenum, GcyA, and Xanthomonas campestris, GuaX, have been shown to possess guanylate cyclase activities. Enzymatic activities of these guanylate cyclases measured in vitro were low, which makes interpretation of the assays ambiguous. Protein sequence analysis at present is insufficient to distinguish between bacterial adenylate and guanylate cyclases, both of which belong to nucleotide cyclases of type III. We developed a simple method for discriminating between guanylate and adenylate cyclase activities in a physiologically relevant bacterial system. The method relies on the use of a mutant cAMP receptor protein, CRP_G, constructed here. While wild‐type CRP is activated exclusively by cAMP, CRP_G can be activated by either cAMP or cGMP. Using CRP‐ and CRP_G‐dependent lacZ expression in two E. coli strains, we verified that R. centenum GcyA and X. campestris GuaX have primarily guanylate cyclase activities. Among two other bacterial nucleotide cyclases tested, one, GuaA from Azospillrillum sp. B510, proved to have guanylate cyclase activity, while the other one, Bradyrhizobium japonicum CyaA, turned out to function as an adenylate cyclase. The results obtained with this reporter system were in excellent agreement with direct measurements of cyclic nucleotides secreted by E. coli expressing nucleotide cyclase genes. The simple genetic screen developed here is expected to facilitate identification of bacterial guanylate cyclases and engineering of guanylate cyclases with desired properties. Proteins 2015; 83:799–804. © 2015 Wiley Periodicals, Inc.     

CyaG, a novel cyanobacterial adenylyl cyclase and a possible ancestor of mammalian guanylyl cyclases

A novel gene encoding an adenylyl cyclase, designated cyaG, was identified in the filamentous cyanobacterium Spirulina platensis. The predicted amino acid sequence of the C-terminal region of cyaG was similar to the catalytic domains of Class III adenylyl and guanylyl cyclases. The N-terminal region next to the catalytic domain of CyaG was similar to the dimerization domain, which is highly conserved among guanylyl cyclases. As a whole, CyaG is more closely related to guanylyl cyclases than to adenylyl cyclases in its primary structure. The catalytic domain of CyaG was expressed in Escherichia coli and partially purified. CyaG showed adenylyl cyclase (but not guanylyl cyclase) activity. By site-directed mutagenesis of three amino acid residues (Lys(533), Ile(603), and Asp(605)) within the purine ring recognition site of CyaG to Glu, Arg, and Cys, respectively, CyaG was transformed to a guanylyl cyclase that produced cGMP instead of cAMP. Thus having properties of both cyclases, CyaG may therefore represent a critical position in the evolution of Class III adenylyl and guanylyl cyclases.     

环氧角鲨烯环化酶在三萜化合物生物合成中的进展

三萜类化合物是植物代谢产物中最具多样性的化合物之一,具有广泛的生理活性和重要的经济价值.环氧角鲨烯环化酶(oxidosqualene cyclases,OSCs)催化2,3-氧化鲨烯环化生成不同类型的甾醇和植物三萜化合物,对天然产物的结构多样性具有重要意义.然而,目前对于OSCs酶催化2,3-氧化鲨烯发生环化多样性的机...     

Relationships between the calmodulin-dependent adenylate cyclases produced by Bacillus anthracis and Bordetella pertussis

The nucleotide sequences for the calmodulin-dependent adenylate cyclases produced by Bordetella pertussis and Bacillus anthracis have recently been determined. The GC% for the B. pertussis and B. anthracis cyclase genes are about 65% and 29%, respectively. Despite this difference in nucleotide composition, these cyclases possess three highly conserved amino acid domains and share some nucleotide sequence homology. One of these conserved domains appears to be involved in ATP binding and is related to the consensus amino acid sequences present in many eukaryotic and prokaryotic ATP and GTP binding proteins. The possible relationship between these cyclases and eukaryotic calmodulin-dependent adenylate cyclases is discussed.     

Mycobacterial adenylyl cyclases: biochemical diversity and structural plasticity

The conversion of adenine and guanine nucleoside triphosphates to cAMP and cGMP is carried out by nucleotide cyclases, which vary in their primary sequence and are therefore grouped into six classes. The class III enzymes encompass all eukaryotic adenylyl and guanylyl cyclase, and several bacterial and archaebacterial cyclases. Mycobacterial nucleotide cyclases show distinct biochemical properties and domain fusions, and we review here biochemical and structural studies on these enzymes from Mycobacterium tuberculosis and related bacteria. We also present an in silico analysis of nucleotide cyclases found in completely sequenced mycobacterial genomes. It is clear that this group of enzymes demonstrates the tinkering in the class III cyclase domain during evolution, involving subtle structural changes that retain the overall catalytic function and fine tune their activities.     

Guanylyl cyclases with the topology of mammalian adenylyl cyclases and an N-terminal P-type ATPase-like domain in Paramecium, Tetrahymena and Plasmodium.

We cloned a guanylyl cyclase of 280 kDa from the ciliate Paramecium which has an N-terminus similar to that of a P-type ATPase and a C-terminus with a topology identical to mammalian adenylyl cyclases. Respective signature sequence motifs are conserved in both domains. The cytosolic catalytic C1a and C2a segments of the cyclase are inverted. Genes coding for topologically identical proteins with substantial sequence similarities have been cloned from Tetrahymena and were detected in sequences from Plasmodium deposited by the Malaria Genome Project. After 99 point mutations to convert the Paramecium TAA/TAG-Gln triplets to CAA/CAG, together with partial gene synthesis, the gene from Paramecium was heterologously expressed. In Sf9 cells, the holoenzyme is proteolytically processed into the two domains. Immunocytochemistry demonstrates expression of the protein in Paramecium and localizes it to cell surface membranes. The data provide a novel structural link between class III adenylyl and guanylyl cyclases and imply that the protozoan guanylyl cyclases evolved from an ancestral adenylyl cyclase independently of the mammalian guanylyl cyclase isoforms. Further, signal transmission in Ciliophora (Paramecium, Tetrahymena) and in the most important endoparasitic phylum Apicomplexa (Plasmodium) is, quite unexpectedly, closely related.     

Structure-functional organization of adenylyl cyclases of unicellular eukaryotes and molecular mechanisms of their regulation

Adenylyl cyclases, the enzymes which catalyze the formation of the second messenger cAMP, are presently known to exist in yeast and related fungi, the amoeba Dictyostelium discoideum, flagellates, plasmodium, and infusoria. However, their structure-functional organization and molecular mechanisms of regulation differ considerably. Thus, in flagellates, tens of structurally similar adenylyl cyclase one-pass transmembrane proteins performing receptor functions have been discovered. In the amoeba D. discoideum, three types of adenylyl cyclases were detected, which differ by their topology, domain organization, and sensitivity to regulatory molecules and physical factors, one of which, adenylyl cyclase-A (AC-A), is similar to mammalian membrane-bound adenylyl cyclases and regulated by extracellular cAMP. Yeasts, in turn, have been shown to possess adenylyl cyclases that do not have transmembrane domains, but are able to form intermolecular complexes stabilized by interactions between repeated regions enriched in leucine residues. The data presented in this review indicate that the main molecular mechanisms underlying the actions of vertebrate adenylyl cyclases evolved as early as in the unicellular organisms and fungi. The structures and functions of adenylyl cyclases of the lower eukaryotes are much more diverse, which might be due both to the peculiarities of their life cycles and to the development at the initial stages of evolution of different models for the functioning and regulation of cAMP-dependent signaling cascades.