Signal transduction systems in prokaryotes

The main components of chemosignaling systems of prokaryotes are multifunctional receptor molecules that include both sensor domains specifically recognizing external signals and effector domains converting these signals into an adequate cell response. This review summarizes and analyzes data on structural-functional organization, molecular mechanisms of action, and regulation of receptor forms of histidine kinases, adenylyl kinases, diguanylyl cyclases, and phosphodiesterases. These enzymes have been shown to be precursors of the receptor and effector components of the eukaryote hormonal signaling systems. This confirms the hypothesis developed by the authors about formation of the main archetypes of chemosignaling systems at the early evolution stages and about the evolutionary relationship of the signaling systems of prokaryotes and eukaryotes.     

Bacterial response regulators: versatile regulatory strategies from common domains

Response regulators (RRs) comprise a major family of signaling proteins in prokaryotes. A modular architecture that consists of a conserved receiver domain and a variable effector domain enables RRs to function as phosphorylation-regulated switches that couple a wide variety of cellular behaviors to environmental cues. Recently, advances have been made in understanding RR functions both at genome-wide and molecular levels. Global techniques have been developed to analyze RR input and output, expanding the scope of characterization of these versatile components. Meanwhile, structural studies have revealed that, despite common structures and mechanisms of function within individual domains, a range of interactions between receiver and effector domains confer great diversity in regulatory strategies, optimizing individual RRs for the specific regulatory needs of different signaling systems.     

Mycobacterium tuberculosis Rv3651 is a triple sensor‐domain protein

The genome of the human pathogen Mycobacterium tuberculosis (Mtb) encodes ～4,400 proteins, but one third of them have unknown functions. We solved the crystal structure of Rv3651, a hypothetical protein with no discernible similarity to proteins with known function. Rv3651 has a three‐domain architecture that combines one cG MP‐specific phosphodiesterases, a denylyl cyclases and F hlA (GAF) domain and two P er‐A RNT‐S im (PAS) domains. GAF and PAS domains are sensor domains that are typically linked to signaling effector molecules. Unlike these sensor‐effector proteins, Rv3651 is an unusual sensor domain‐only protein with highly divergent sequence. The structure suggests that Rv3651 integrates multiple different signals and serves as a scaffold to facilitate signal transfer.     

The signaling helix: a common functional theme in diverse signaling proteins

Background  

The mechanism by which the signals are transmitted between receptor and effector domains in multi-domain signaling proteins is poorly understood.     

Guanylyl cyclases of unicellular eukaryotes: structure, function, and regulatory properties

Guanylyl cyclases (GCs), catalyzing the synthesis of the second messenger cGMP, are key elements of the signaling systems of animals of different phylogenetic levels including unicellular eukaryotes. In the review the literature data concerning unusual GCs observed in unicellular eukaryotes and having the structural-functional organization and topology similar to those of mammalian membrane-bound adenylyl cyclases, are analyzed. Among these GCs there are bifunctional membrane-bound GCs of ciliates and Plasmodium, which have both C-terminal cyclase domain related to mammalian adenylyl cyclases and N-terminal domain with ten membrane-spanning regions homologous to P-type ATPases. The developed by the author comparative analysis of primary structures of GC ATPase domains showed that the domains are high conservative and the motifs, which are closely linked to functional activity of ATPase transporters, are preserved in the domains. It is suggested that ATPase domains carry out either receptor or regulatory functions in GC molecules. Dual substrate specificity of cyclases of unicellular organisms and its possible role in revealing of GC activity in fungi and trypanosomes, lacking GC encoded genes, are discussed. The molecular mechanisms of the functioning of GCs, the regulation of GC activity by different agents, and the participation of these enzymes in control of the processes, such as chemotaxis, aggregation, movement, gametogenesis and photophobis response, are analyzed.     

Comparative Analysis of the Flax Immune Receptors L6 and L7 Suggests an Equilibrium-Based Switch Activation Model

NOD-like receptors (NLRs) are central components of the plant immune system. L6 is a Toll/interleukin-1 receptor (TIR) domain-containing NLR from flax (Linum usitatissimum) conferring immunity to the flax rust fungus. Comparison of L6 to the weaker allele L7 identified two polymorphic regions in the TIR and the nucleotide binding (NB) domains that regulate both effector ligand-dependent and -independent cell death signaling as well as nucleotide binding to the receptor. This suggests that a negative functional interaction between the TIR and NB domains holds L7 in an inactive/ADP-bound state more tightly than L6, hence decreasing its capacity to adopt the active/ATP-bound state and explaining its weaker activity in planta. L6 and L7 variants with a more stable ADP-bound state failed to bind to AvrL567 in yeast two-hybrid assays, while binding was detected to the signaling active variants. This contrasts with current models predicting that effectors bind to inactive receptors to trigger activation. Based on the correlation between nucleotide binding, effector interaction, and immune signaling properties of L6/L7 variants, we propose that NLRs exist in an equilibrium between ON and OFF states and that effector binding to the ON state stabilizes this conformation, thereby shifting the equilibrium toward the active form of the receptor to trigger defense signaling.     

Molecular details of cAMP generation in mammalian cells: a tale of two systems

The second messenger cAMP has been extensively studied for half a century, but the plethora of regulatory mechanisms controlling cAMP synthesis in mammalian cells is just beginning to be revealed. In mammalian cells, cAMP is produced by two evolutionary related families of adenylyl cyclases, soluble adenylyl cyclases (sAC) and transmembrane adenylyl cyclases (tmAC). These two enzyme families serve distinct physiological functions. They share a conserved overall architecture in their catalytic domains and a common catalytic mechanism, but they differ in their sub-cellular localizations and responses to various regulators. The major regulators of tmACs are heterotrimeric G proteins, which transduce extracellular signals via G protein-coupled receptors. sAC enzymes, in contrast, are regulated by the intracellular signaling molecules bicarbonate and calcium. Here, we discuss and compare the biochemical, structural and regulatory characteristics of the two mammalian AC families. This comparison reveals the mechanisms underlying their different properties but also illustrates many unifying themes for these evolutionary related signaling enzymes.     

'Life-style' control networks in Escherichia coli: signaling by the second messenger c-di-GMP

Most bacteria can exist in either a planktonic-motile single-cell state or an adhesive multicellular state known as a biofilm. Biofilms cause medical problems and technical damage since they are resistant against antibiotics, disinfectants or the attacks of the immune system. In recent years it has become clear that most bacteria use cyclic diguanylate (c-di-GMP) as a biofilm-promoting second messenger molecule. C-di-GMP is produced by GGDEF-domain-containing diguanylate cyclases and is degraded by phosphodiesterases featuring EAL or HD-GYP domains. Many bacterial species possess multiple proteins with GGDEF and EAL domains, which actually belong to the most abundant protein families in genomic data bases. Via an unprecedented variety of effector components, which include c-di-GMP-binding proteins as well as RNAs, c-di-GMP controls a wide range of targets that down-regulate motility, stimulate adhesin and biofilm matrix formation or even control virulence gene expression. Moreover, local c-di-GMP signaling in macromolecular complexes seems to allow the independent and parallel control of different output reactions. In this review, we use Escherichia coli as a paradigm for c-di-GMP signaling. Despite the huge diversity of components and molecular processes involved in biofilm formation throughout the bacterial kingdom, c-di-GMP signaling represents a unifying principle, which suggests that the enzymes that make and break c-di-GMP may be promising targets for anti-biofilm drugs.     

Structural features of heterotrimeric G-protein-coupled receptors and their modulatory proteins

Over the past 20 years, the general mechanism for signaling through 7-transmembrane helix receptors coupled to GTP hydrolysis has been worked out. Although similar in overall organization, subtype variability and subcellular localization of components have built in considerable signaling specificity. Atomic resolution structures for many of the components have delineated the domain organization of these complex proteins and have given physical form to the idea of subtype specificity. This review describes what is known about the physical structures of the 7-transmembrane helix receptors, the heterotrimeric GTP binding coupling proteins, the adenylate cyclase and phospholipase C effector proteins, and signaling modulatory proteins, such as arrestin, phosducin, recoverin-type myristoyl switch proteins, and the pleckstrin homology domain of G-protein receptor kinase-2. These images allow experimenters to contemplate the details of the supramolecular organization of the multiprotein complexes involved in the transmission of signals across the cellular lipid bilayer.     

Structure of the Cmr2 subunit of the CRISPR-Cas RNA silencing complex

Cmr2 is the largest and an essential subunit of?a CRISPR RNA-Cas protein complex (the Cmr complex) that cleaves foreign RNA to protect prokaryotes from invading genetic elements. Cmr2 is thought to be the catalytic subunit of the effector complex because of its N-terminal HD nuclease domain. Here, however, we report that the HD domain of Cmr2 is not required for cleavage by the complex in?vitro. The 2.3? crystal structure of Pyrococcus furiosus Cmr2 (lacking the HD domain) reveals two adenylyl cyclase-like and two α-helical domains. The adenylyl cyclase-like domains are arranged as in homodimeric adenylyl cyclases and bind ADP and divalent metals. However, mutagenesis studies show that the metal- and ADP-coordinating residues of Cmr2 are also not critical for cleavage by the complex. Our findings suggest that another component provides the catalytic function and that the essential role by Cmr2 does not require the identified ADP- or metal-binding or HD domains in?vitro.     

The Evolution of Guanylyl Cyclases as Multidomain Proteins: Conserved Features of Kinase-Cyclase Domain Fusions

Guanylyl cyclases (GCs) are enzymes that generate cyclic GMP and regulate different physiologic and developmental processes in a number of organisms. GCs possess sequence similarity to class III adenylyl cyclases (ACs) and are present as either membrane-bound receptor GCs or cytosolic soluble GCs. We sought to determine the evolution of GCs using a large-scale bioinformatic analysis and found multiple lineage-specific expansions of GC genes in the genomes of many eukaryotes. Moreover, a few GC-like proteins were identified in prokaryotes, which come fused to a number of different domains, suggesting allosteric regulation of nucleotide cyclase activity. Eukaryotic receptor GCs are associated with a kinase homology domain (KHD), and phylogenetic analysis of these proteins suggest coevolution of the KHD and the associated cyclase domain as well as a conservation of the sequence and the size of the linker region between the KHD and the associated cyclase domain. Finally, we also report the existence of mimiviral proteins that contain putative active kinase domains associated with a cyclase domain, which could suggest early evolution of the fusion of these two important domains involved in signal transduction. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Hypothesis of evolutionary origin of several human and animal diseases

Studies of our Laboratory in the field of molecular and evolutionary endocrinology have allowed us to put forward a hypothesis about evolutionary origin of endocrine and other diseases of human and animals. This hypothesis is considered using a model of hormonal signaling systems. It is based on the concept formulated by the authors about molecular defects in hormonal signaling systems as the key causes of endocrine diseases; on evolutionary conservatism of hormonal signaling systems, which stems logically from the authors’ concept of the prokaryotic genesis and endosymbiotic emergence in the course of evolution of chemosignaling systems in the higher eukaryotes; from the fact that the process of formation of hormonal signaling systems with participation of endosymbiosis including the horizontal transfer of genes is accompanied by transfer not only of normal, but also of the defected genetic material. There are considered examples of the principal possibility of transfer of defected genes between bacteria and eukaryotic organisms. Analysis of the current literature allows suggesting inheritance of pathogenic factors from evolutionary ancestors in the lineage prokaryotes—lower eukaryotes—higher eukaryotes.     

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.     

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.     

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.     

A different TIPE of immune homeostasis

Proteins with death effector domains (DED) are key signal transducers involved in cell death and inflammation. In this issue of Cell, Sun et al. (2008) describe TIPE2, a DED protein that negatively regulates both T cell receptor and Toll-like receptor signaling. These findings reveal a new element critical to the maintenance of homeostasis in both the adaptive and innate immune systems.     

One-component systems dominate signal transduction in prokaryotes

Two-component systems that link environmental signals to cellular responses are viewed as the primary mode of signal transduction in prokaryotes. By analyzing information encoded by 145 prokaryotic genomes, we found that the majority of signal transduction systems consist of a single protein that contains input and output domains but lacks phosphotransfer domains typical of two-component systems. One-component systems are evolutionarily older, more widely distributed among bacteria and archaea, and display a greater diversity of domains than two-component systems.