Molecular modeling and functional analysis of the AtoS–AtoC two-component signal transduction system of Escherichia coli

The bacterial division protein MinDE has an independent function in flagellation

Before preparing for division, bacteria stop their motility. During the exponential growth phase in Escherichia coli, when the rate of bacterial division is highest, the expression of flagellar genes is repressed and bacterial adhesion is enhanced. Hence, it is evident that cell division and motility in bacteria are linked; however, the specific molecular mechanism by which these two processes are linked is not known. While observing E. coli, we found that compared to the WT, the E. coli (Δmin) cells show higher motility and flagellation. We demonstrated that the higher motility was due to the absence of the Min system and can be restored to normal in the presence of Min proteins, where Min system negatively regulates flagella formation. The Min system in E. coli is widely studied for its role in the inhibition of polar Z-ring formation through its pole-to-pole oscillation. However, its role in bacterial motility is not explored. MinD homologs, FlhG and FleN, are known to control flagellar expression through their interaction with FlrA and FleQ, respectively. AtoC, a part of the two-component system AtoSC complex, is homologous to FlrA/FleQ, and the complex is involved in E. coli flagellation via its interaction with the fliA promoter. We have shown that MinD interacts directly with the AtoS of AtoSC complex and controls the fliA expression. Our findings suggest that the Min system acts as a link between cell division and motility in E. coli.

Natural intelligence and the 'economy' of social emotions: A connection with AI sentiment analysis

By approaching the concept of Natural Intelligence a new path may be open in a variety of theoretical and applied problems on social emotions. There is no doubt that intelligence emerges as a biological/informational phenomenon, although paradoxically a consistent elaboration of that concept has been missing. Regarding emotions, they have been keeping an unclear status, being often restricted to the anthropological or to ethological approaches closer to the behaviorist paradigm. Herein we propose a different track, centered in the life cycle advancement. The life cycle in its integrity becomes the nucleus of natural intelligence's informational processes, including the consistent expression of emotions along the maximization of fitness occasions. In human societies, the overall 'economy' of social emotions is manifest, showing up in the conspicuous interplay between bonding processes and different classes of social emotions. The essential link between natural intelligence, emotions, and the life cycle of individuals may harmonize with current progresses - and blind spots - of artificial intelligence fields such as 'sentiment analysis.'

The AtoC family response regulator upregulates an operon encoding putative outer membrane proteins sorted by type IX secretion system in Porphyromonas gingivalis

OBJECTIVES

Porphyromonas gingivalis, a keystone periodontopathogen, has multiple two-component systems that are thought to modulate virulence. In this study, we focused on PGN_0775 response regulator (RR), an AtoC homolog, and attempted to identify the target gene that it regulates in P. gingivalis.

METHODS

Comparative proteomic analyses comprising two-dimensional electrophoresis and peptide mass fingerprinting were applied to total protein samples from parent (WT) and atoC gene knockout (KO) strains to screen for affected protein spots. Fluctuations in the expression of corresponding genes were further confirmed using relative quantitative real-time polymerase chain reaction (RQPCR).

RESULTS

Five protein spots with fluctuating expression levels were identified in pgn_0775 KO strains along with their masses and physiological features, which contained two hypothetical proteins with higher expression levels in the WT than in the KO strains. RQPCR analysis confirmed that mRNA levels were consistently decreased in KO and recovered in pgn_0775-complemented KO strains. The two hypothetical proteins appeared to be the products of an operon that comprises four genes encoding three hypothetical but putative type IX secretion system sorting domain-containing proteins and an N-terminal region of the C25 cysteine peptidase.

CONCLUSIONS

The AtoC RR homolog in P. gingivalis upregulates the expression of the operon encoding potentially antigenic proteins retained on the cell surface; thus, it could be a promising target for P. gingivalis-specific antivirulence therapy.

From Molecular Recognition to the "Vehicles" of Evolutionary Complexity: An Informational Approach

Countless informational proposals and models have explored the singular characteristics of biological systems: from the initial choice of information terms in the early days of molecular biology to the current bioinformatic avalanche in this “omic” era. However, this was conducted, most often, within partial, specialized scopes or just metaphorically. In this paper, we attempt a consistent informational discourse, initially based on the molecular recognition paradigm, which addresses the main stages of biological organization in a new way. It considers the interconnection between signaling systems and information flows, between informational architectures and biomolecular codes, between controlled cell cycles and multicellular complexity. It also addresses, in a new way, a central issue: how new evolutionary paths are opened by the cumulated action of multiple variation engines or mutational ‘vehicles’ evolved for the genomic exploration of DNA sequence space. Rather than discussing the possible replacement, extension, or maintenance of traditional neo-Darwinian tenets, a genuine informational approach to evolutionary phenomena is advocated, in which systemic variation in the informational architectures may induce differential survival (self-construction, self-maintenance, and reproduction) of biological agents within their open ended environment.

Sigma 54-Regulated Transcription Is Associated with Membrane Reorganization and Type III Secretion Effectors during Conversion to Infectious Forms of Chlamydia trachomatis

The factors that control the growth and infectious processes for Chlamydia are still poorly understood. This study used recently developed genetic tools to determine the regulon for one of the key transcription factors encoded by Chlamydia, sigma 54. Surrogate and computational analyses provide additional support for the hypothesis that sigma 54 plays a key role in controlling the expression of many components critical to converting and enabling the infectious capability of Chlamydia. These components include those that remodel the membrane for the extracellular environment and incorporation of an arsenal of type III secretion effectors in preparation for infecting new cells.

Chlamydia bacteria are obligate intracellular organisms with a phylum-defining biphasic developmental cycle that is intrinsically linked to its ability to cause disease. The progression of the chlamydial developmental cycle is regulated by the temporal expression of genes predominantly controlled by RNA polymerase sigma (σ) factors. Sigma 54 (σ⁵⁴) is one of three sigma factors encoded by Chlamydia for which the role and regulon are unknown. CtcC is part of a two-component signal transduction system that is requisite for σ⁵⁴ transcriptional activation. CtcC activation of σ⁵⁴ requires phosphorylation, which relieves inhibition by the CtcC regulatory domain and enables ATP hydrolysis by the ATPase domain. Prior studies with CtcC homologs in other organisms have shown that expression of the ATPase domain alone can activate σ⁵⁴ transcription. Biochemical analysis of CtcC ATPase domain supported the idea of ATP hydrolysis occurring in the absence of the regulatory domain, as well as the presence of an active-site residue essential for ATPase activity (E242). Using recently developed genetic approaches in Chlamydia to induce expression of the CtcC ATPase domain, a transcriptional profile was determined that is expected to reflect the σ⁵⁴ regulon. Computational evaluation revealed that the majority of the differentially expressed genes were preceded by highly conserved σ⁵⁴ promoter elements. Reporter gene analyses using these putative σ⁵⁴ promoters reinforced the accuracy of the model of the proposed regulon. Investigation of the gene products included in this regulon supports the idea that σ⁵⁴ controls expression of genes that are critical for conversion of Chlamydia from replicative reticulate bodies into infectious elementary bodies.

How prokaryotes 'encode' their environment: Systemic tools for organizing the information flow

An important issue related to code biology concerns the cell's informational relationships with the environment. As an open self-producing system, a great variety of inputs and outputs are necessary for the living cell, not only consisting of matter and energy but also involving information flows. The analysis here of the simplest cells will involve two basic aspects. On the one side, the molecular apparatuses of the prokaryotic signaling system, with all its variety of environmental signals and component pathways (which have been called 1-2-3 Component Systems), including the role of a few second messengers which have been pointed out in bacteria too. And in the other side, the gene transcription system as depending not only on signaling inputs but also on a diversity of factors. Amidst the continuum of energy, matter, and information flows, there seems to be evidence for signaling codes, mostly established around the arrangement of life-cycle stages, in large metabolic changes, or in the relationships with conspecifics (quorum sensing) and within microbial ecosystems. Additionally, and considering the complexity growth of signaling systems from prokaryotes to eukaryotes, four avenues or "roots" for the advancement of such complexity would come out. A comparative will be established in between the signaling strategies and organization of both kinds of cellular systems. Finally, a new characterization of "informational architectures" will be proposed in order to explain the coding spectrum of both prokaryotic and eukaryotic signaling systems. Among other evolutionary aspects, cellular strategies for the construction of novel functional codes via the intermixing of informational architectures could be related to the persistence of retro-elements with obvious viral ancestry.

On eukaryotic intelligence: signaling system's guidance in the evolution of multicellular organization

Communication with the environment is an essential characteristic of the living cell, even more when considering the origins and evolution of multicellularity. A number of changes and tinkering inventions were necessary in the evolutionary transition between prokaryotic and eukaryotic cells, which finally made possible the appearance of genuine multicellular organisms. In the study of this process, however, the transformations experimented by signaling systems themselves have been rarely object of analysis, obscured by other more conspicuous biological traits: incorporation of mitochondria, segregated nucleus, introns/exons, flagellum, membrane systems, etc. Herein a discussion of the main avenues of change from prokaryotic to eukaryotic signaling systems and a review of the signaling resources and strategies underlying multicellularity will be attempted. In the expansion of prokaryotic signaling systems, four main systemic resources were incorporated: molecular tools for detection of solutes, molecular tools for detection of solvent (Donnan effect), the apparatuses of cell-cycle control, and the combined system endocytosis/cytoskeleton. The multiple kinds of enlarged, mixed pathways that emerged made possible the eukaryotic revolution in morphological and physiological complexity. The massive incorporation of processing resources of electro-molecular nature, derived from the osmotic tools counteracting the Donnan effect, made also possible the organization of a computational tissue with huge information processing capabilities: the nervous system. In the central nervous systems of vertebrates, and particularly in humans, neurons have achieved both the highest level of molecular-signaling complexity and the highest degree of information-processing adaptability. Theoretically, it can be argued that there has been an accelerated pace of evolutionary change in eukaryotic signaling systems, beyond the other general novelties introduced by eukaryotic cells in their handling of DNA processes. Under signaling system's guidance, the whole processes of transcription, alternative splicing, mobile elements, and other elements of domain recombination have become closely intertwined and have propelled the differentiation capabilities of multicellular tissues and morphologies. An amazing variety of signaling and self-construction strategies have emerged out from the basic eukaryotic design of multicellular complexity, in millions and millions of new species evolved. This design can also be seen abstractly as a new kind of quasi-universal problem-solving 'engine' implemented at the biomolecular scale-providing the fundamentals of eukaryotic 'intelligence'. Analyzing in depth the problem-solving intelligence of eukaryotic cells would help to establish an integrative panorama of their information processing organization, and of their capability to handle the morphological and physiological complexity associated. Whether an informational updating of the venerable "cell theory" is feasible or not, becomes, at the time being - right in the middle of the massive data deluge/revolution from omic disciplines - a matter to careful consider.

Regulation of poly-(R)-(3-hydroxybutyrate-co-3-hydroxyvalerate) biosynthesis by the AtoSCDAEB regulon in phaCAB+ Escherichia coli

AtoSC two-component system (TCS) upregulates the high-molecular weight poly-(R)-3-hydroxybutyrate (PHB) biosynthesis in recombinant phaCAB (+) Escherichia coli strains, with the Cupriavidus necator phaCAB operon. We report here that AtoSC upregulates also the copolymer P(3HB-co-3HV) biosynthesis in phaCAB (+) E. coli. Acetoacetate-induced AtoSC maximized P(3HB-co-3HV) to 1.27 g/l with a 3HV fraction of 25.5 % wt. and biopolymer content of 75 % w/w in a time-dependent process. The atoSC locus deletion in the ∆atoSC strains resulted in 4.5-fold P(3HB-co-3HV) reduction, while the 3HV fraction of the copolymer was restricted to only 6.4 % wt. The ∆atoSC phenotype was restored by extrachromosomal introduction of AtoSC. Deletion of the atoDAEB operon triggered a significant decrease in P(3HB-co-3HV) synthesis and 3HV content in ∆atoDAEB strains. However, the acetoacetate-induced AtoSC in those strains increased P(3HB-co-3HV) to 0.8 g/l with 21 % 3HV, while AtoC or AtoS expression increased P(3HB-co-3HV) synthesis 3.6- or 2.4-fold, respectively, upon acetoacetate. Complementation of the ∆atoDAEB phenotype was achieved by the extrachromosomal introduction of the atoSCDAEB regulon. Individual inhibition of β-oxidation and mainly fatty acid biosynthesis pathways by acrylic acid or cerulenin, respectively, reduced P(3HB-co-3HV) biosynthesis. Under those conditions, introduction of atoSC or atoSCDAEB regulon was capable of upregulating biopolymer accumulation. Concurrent inhibition of both the fatty acid metabolic pathways eliminated P(3HB-co-3HV) production. P(3HB-co-3HV) upregulation in phaCAB (+) E. coli by AtoSC signaling through atoDAEB operon and its participation in the fatty acids metabolism interplay provide additional perceptions of AtoSC critical involvement in E. coli regulatory processes towards biotechnologically improved polyhydroxyalkanoates biosynthesis.

Involvement of AtoSC two-component system in Escherichia coli flagellar regulon

The AtoSC two-component system in Escherichia coli is a key regulator of many physiological processes. We report here the contribution of AtoSC in E. coli motility and chemotaxis. AtoSC locus deletion in ΔatoSC cells renders cells not motile or responsive against any chemoattractant or repellent independently of the AtoSC inducer's presence. AtoSC expression through plasmid complemented the ΔatoSC phenotype. Cells expressing either AtoS or AtoC demonstrated analogous motility and chemotactic phenotypes as ΔatoSC cells, independently of AtoSC inducer's presence. Mutations of AtoC phosphate-acceptor sites diminished or abrogated E. coli chemotaxis. trAtoC, the AtoC constitutive active form which lacks its receiver domain, up-regulated E. coli motility. AtoSC enhanced the transcription of the flhDC and fliAZY operons and to a lesser extent of the flgBCDEFGHIJKL operon. The AtoSC-mediated regulation of motility and chemotactic response required also the expression of the CheAY system. The AtoSC inducers enhanced the AtoSC-mediated motility and chemotaxis. Acetoacetate or spermidine further promoted the responses of only AtoSC-expressing cells, while Ca(2+) demonstrated its effects independently of AtoSC. Histamine regulated bacterial chemotaxis only in atoSC (+) cells in a concentration-dependent manner while reversed the AtoSC-mediated effects when added at high concentrations. The trAtoC-controlled motility effects were enhanced by acetoacetate or spermidine, but not by histamine. These data reveal that AtoSC system regulates the motility and chemotaxis of E. coli, participating in the transcriptional induction of the main promoters of the chemotactic regulon and modifying the motility and chemotactic phenotypes in an induction-dependent mechanism.

Escherichia coli genome-wide promoter analysis: identification of additional AtoC binding target elements

Background

Studies on bacterial signal transduction systems have revealed complex networks of functional interactions, where the response regulators play a pivotal role. The AtoSC system of E. coli activates the expression of atoDAEB operon genes, and the subsequent catabolism of short-chain fatty acids, upon acetoacetate induction. Transcriptome and phenotypic analyses suggested that atoSC is also involved in several other cellular activities, although we have recently reported a palindromic repeat within the atoDAEB promoter as the single, cis-regulatory binding site of the AtoC response regulator. In this work, we used a computational approach to explore the presence of yet unidentified AtoC binding sites within other parts of the E. coli genome.

Results

Through the implementation of a computational de novo motif detection workflow, a set of candidate motifs was generated, representing putative AtoC binding targets within the E. coli genome. In order to assess the biological relevance of the motifs and to select for experimental validation of those sequences related robustly with distinct cellular functions, we implemented a novel approach that applies Gene Ontology Term Analysis to the motif hits and selected those that were qualified through this procedure. The computational results were validated using Chromatin Immunoprecipitation assays to assess the in vivo binding of AtoC to the predicted sites. This process verified twenty-two additional AtoC binding sites, located not only within intergenic regions, but also within gene-encoding sequences.

Conclusions

This study, by tracing a number of putative AtoC binding sites, has indicated an AtoC-related cross-regulatory function. This highlights the significance of computational genome-wide approaches in elucidating complex patterns of bacterial cell regulation.

Dimerization of the AtoC response regulator and modelling of its binding to DNA

Bacterial signal transduction systems can be viewed as an entity of multi-sensory and output domains, whereas the functions of response regulators play a pivotal role in the complex network interactions. One crucial property among response regulators functions is their oligomerization and subsequent binding to DNA. The AtoS-AtoC two component system, functionally modulated by various agents, influences fundamental cellular processes such as short-chain fatty acid catabolism and poly-(R)-3-hydroxybutyrate biosynthesis in Escherichia coli. Among the already reported characteristic properties, AtoC binds to a specific site, a palindromic repeat of 20 nucleotides within the atoDAEB promoter. Since experimental structures of AtoC or its complex with DNA are not yet available, an almost complete homology model of AtoC and of its putative entity as a dimer is constructed for this study, as well as a model of its binding to its target DNA sequence. The latter is associated with large conformational changes, as shown by molecular dynamics simulations. Subsequent biochemical study, including cross-linking via chemical agents, revealed the ability of AtoC to form oligomers in vitro.

Multiple controls affect arsenite oxidase gene expression in Herminiimonas arsenicoxydans

BACKGROUND

Both the speciation and toxicity of arsenic are affected by bacterial transformations, i.e. oxidation, reduction or methylation. These transformations have a major impact on environmental contamination and more particularly on arsenic contamination of drinking water. Herminiimonas arsenicoxydans has been isolated from an arsenic- contaminated environment and has developed various mechanisms for coping with arsenic, including the oxidation of As(III) to As(V) as a detoxification mechanism.

RESULTS

In the present study, a differential transcriptome analysis was used to identify genes, including arsenite oxidase encoding genes, involved in the response of H. arsenicoxydans to As(III). To get insight into the molecular mechanisms of this enzyme activity, a Tn5 transposon mutagenesis was performed. Transposon insertions resulting in a lack of arsenite oxidase activity disrupted aoxR and aoxS genes, showing that the aox operon transcription is regulated by the AoxRS two-component system. Remarkably, transposon insertions were also identified in rpoN coding for the alternative N sigma factor (sigma54) of RNA polymerase and in dnaJ coding for the Hsp70 co-chaperone. Western blotting with anti-AoxB antibodies and quantitative RT-PCR experiments allowed us to demonstrate that the rpoN and dnaJ gene products are involved in the control of arsenite oxidase gene expression. Finally, the transcriptional start site of the aoxAB operon was determined using rapid amplification of cDNA ends (RACE) and a putative -12/-24 sigma54-dependent promoter motif was identified upstream of aoxAB coding sequences.

CONCLUSION

These results reveal the existence of novel molecular regulatory processes governing arsenite oxidase expression in H. arsenicoxydans. These data are summarized in a model that functionally integrates arsenite oxidation in the adaptive response to As(III) in this microorganism.

On prokaryotic intelligence: strategies for sensing the environment

The adaptive relationship with the environment is a sine qua non condition for any intelligent system. Discussions on the nature of cellular intelligence, however, have not systematically pursued yet the question of whether there is a fundamental way of sensing the environment, which may characterize prokaryotic cells, or not. The molecular systems found in bacterial signaling are extremely diverse, ranging from very simple transcription regulators (single proteins comprising just two domains) to the multi-component, multi-pathway signaling cascades that regulate crucial stages of the cell cycle, such as sporulation, biofilm formation, dormancy, pathogenesis or flagellar biosynthesis. The combined complexity of the environment and of the cellular way of life is reflected as a whole in the aggregate of signaling elements: an interesting power-law relationship emerges in that regard. In a basic taxonomy of bacterial signaling systems, the first level of complexity corresponds to the simplest regulators, the "one-component systems" (OCSs), which are defined as proteins that contain known or predicted input and output domains but lack histidine kinase and receiver domains. They are evolutionary precursors of the "two-component systems" (TCSs), which include histidine protein-kinase receptors and an independent response regulator, and are considered as the central signaling paradigm within prokaryotic organisms. The addition of independent receptors begets further functional complexity: thus, "three-component systems" (ThCSs) should be applied to those two-component systems that incorporate an extra non-kinase receptor to activate the protein-kinase. Further, the combined information processing functions (cross-talk) and integrative dynamics that OCS, TCS and ThCS may achieve together in the prokaryotic cell have to be depicted, as well as the relationship of these informational functions with the life cycle organization and its checkpoints. Finally, the extent to which formal models would capture the ongoing relationship of the living cell with its medium has to be gauged, in the light of both the complexity of molecular recognition events and the impredicative nature of living systems.

Signal transduction and adaptive regulation through bacterial two-component systems: the Escherichia coli AtoSC paradigm

Adaptive signal transduction within microbial cells involves a multi-faceted regulated phosphotransfer mechanism that comprises structural rearrangements of sensor histidine kinases upon ligand-binding and phosphorylation-induced conformational changes in response regulators of versatile two-component systems (TCS), arisen early in bacterial evolution. In Escherichia coli, cross-talk between the AtoS histidine kinase and the AtoC response regulator, forming the AtoSC TCS, through His --> Asp phosphotransfer, activates AtoC directly to induce atoDAEB operon expression, thus modulating diverse fundamental cellular processes such as short-chain fatty acid catabolism, poly-(R)-3-hydroxybutyrate biosynthesis and chemotaxis. Among the inducers hitherto identified, acetoacetate is the classical activator. The AtoSC TCS functional modulation by polyamines, histamine and Ca(2+), as well as the role of AtoC as transcriptional regulator, add new promising perspectives in the physiological significance and potential pharmacological exploitation of this TCS in cell proliferation, bacteria-host interactions, chemotaxis, and adaptation.

Functional characterization of the histidine kinase of the E. coli two-component signal transduction system AtoS-AtoC

The Escherichia coli AtoS-AtoC two-component signal transduction system regulates the expression of the atoDAEB operon genes, whose products are required for short-chain fatty acid catabolism. In this study purified his-tagged wild-type and mutant AtoS proteins were used to prove that these proteins are true sensor kinases. The phosphorylated residue was identified as the histidine-398, which was located in a conserved Eta-box since AtoS carrying a mutation at this site failed to phosphorylate. This inability to phosphorylate was not due to gross structural alterations of AtoS since the H398L mutant retained its capability to bind ATP. Furthermore, the H398L mutant AtoS was competent to catalyze the trans-phosphorylation of an AtoS G-box (G565A) mutant protein which otherwise failed to autophosphorylate due to its inability to bind ATP. The formation of homodimers between the various AtoS proteins was also shown by cross-linking experiments both in vitro and in vivo.

Effect of histamine on the signal transduction of the AtoS-AtoC two component system and involvement in poly-(R)-3-hydroxybutyrate biosynthesis in Escherichia coli

AtoS-AtoC two-component system acts directly on the atoDAEB operon transcription to regulate the biosynthesis of short-chain poly-(R)-3-hydroxybutyrate. This study sought to investigate the effect of histamine and compound 48/80 on the regulation of AtoS-AtoC two-component system in Escherichia coli K-12 MA255 (speC(-), speB(-)) and the isogenic E. coli strains BW25113 (atoSC(+)) and BW28878 (DeltaatoSC) transformed with plasmids carrying related genes. Histamine or compound 48/80 induced or tended to reduce atoC transcription, respectively, while neither compound showed any effect on atoDAEB operon transcription. Moreover, histamine down-regulated poly-(R)-3-hydroxybutyrate biosynthesis, whereas compound 48/80 up-regulated its biosynthesis, maximal induction being obtained in the presence of multiple copies of AtoS-AtoC. Interestingly, co-administration of histamine counteracted this inductive effect of compound 48/80. The reported data provide the first evidence for a differential modulator role of histamine and compound 48/80 on the AtoS-AtoC two-component system signaling in potentially pathogenic bacteria, leading to a new perspective on their symbiotic behavior.