Trp Operon Research Articles

Структурное разнообразие триптофанового оперона и лидерного пептида TrpL у представителей Enterobacteria

Структурное разнообразие триптофанового оперона и лидерного пептида TrpL у представителей Enterobacteria

Synthesis and evaluation of biological activity of benzoxaborole derivatives of azithromycin.

Novel benzoxaborole derivatives of azithromycin in which benzoxaborole residue is attached to the 4″-hydroxy-group of azithromycin have been synthesized. Antibacterial activity of synthesized derivatives in comparison with azithromycin was tested on a panel of Gram-positive and Gram-negative bacterial strains. All the investigated compounds demonstrated broad spectrum of antibacterial activity being in general more active against Gram-positive strains. New benzoxaborole derivatives of azithromycin demonstrated high activity against Streptococcus pyogenes ATCC 19615 and Propionibacterium acnes ATCC 6919 strains. Some of the new compounds were more active than azithromycin against Streptococcus pneumoniae ATCC 49619 strain or Enterococcus faecium strains. Using a reporter construct created on the basis of the transcription attenuator region of the Escherichia coli tryptophan operon pRFPCER-TrpL2A it has been demonstrated that the mechanism of action of azithromycin analogs is blocking nascent peptide in ribosome tunnel.

Global behaviors analysis for tryptophan operon system with bounded noise

• A new stochastic model is proposed for the bioprocess of regulation of bacterial trp operon. • The control sets in the control system are computed by a parallel CS algorithm. • The global behavior of the stochastic model is analyzed. Global behavior for stochastic system of regulation of bacterial tryptophan ( trp ) operon is analyzed in this paper. This bioprocess cannot avoid the internal and external disturbances reflected on the cell growth rate within the biosynthesis of trp . These factors can affect the integrated results of repression and attenuation, leading to genetic circuit or switch. The equilibria and bifurcations of the deterministic system are analyzed. Then, a stochastic model is presented by considering the effect of a bounded Markov diffusion process on critical parameters. In order to analyze the global behavior, we compute the control sets through solving the associated control system by using parallel control set algorithm. In particular, we compute the bifurcation as discontinuous topology changes in the support of a stationary measure. The probability distributions of relative supports are also provided. The results provide indication on how the disturbances affect the bioprocess with sustained oscillations.

Bacterial gene control by DNA looping using engineered dimeric transcription activator like effector (TALE) proteins.

Genetic switches must alternate between states whose probabilities are dependent on regulatory signals. Classical examples of transcriptional control in bacteria depend on repressive DNA loops anchored by proteins whose structures are sensitive to small molecule inducers or co-repressors. We are interested in exploiting these natural principles to engineer artificial switches for transcriptional control of bacterial genes. Here, we implement designed homodimeric DNA looping proteins (‘Transcription Activator-Like Effector Dimers’; TALEDs) for this purpose in living bacteria. Using well-studied FKBP dimerization domains, we build switches that mimic regulatory characteristics of classical Escherichia coli lactose, galactose and tryptophan operon promoters, including induction or co-repression by small molecules. Engineered DNA looping using TALEDs is thus a new approach to tuning gene expression in bacteria. Similar principles may also be applicable for gene control in eukaryotes.

Discovering Prokaryotic Gene Regulation with Simulations of the trp Operon

Discovering Prokaryotic Gene Regulation with Simulations of the trp Operon

Repetitive Short-Term Stimuli Imposed in Poor Mixing Zones Induce Long-Term Adaptation of E. coli Cultures in Large-Scale Bioreactors: Experimental Evidence and Mathematical Model.

Rapidly changing concentrations of substrates frequently occur during large-scale microbial cultivations. These changing conditions, caused by large mixing times, result in a heterogeneous population distribution. Here, we present a powerful and efficient modeling approach to predict the influence of varying substrate levels on the transcriptional and translational response of the cell. This approach consists of two parts, a single-cell model to describe transcription and translation for an exemplary operon (trp operon) and a second part to characterize cell distribution during the experimental setup. Combination of both models enables prediction of transcriptional patterns for the whole population. In summary, the resulting model is not only able to anticipate the experimentally observed short-term and long-term transcriptional response, it further allows envision of altered protein levels. Our model shows that locally induced stress responses propagate throughout the bioreactor, resulting in temporal, and spatial population heterogeneity. Stress induced transcriptional response leads to a new population steady-state shortly after imposing fluctuating substrate conditions. In contrast, the protein levels take more than 10 h to achieve steady-state conditions.

Identification of a Residue (Glu60) in TRAP Required for Inducing Efficient Transcription Termination at the trp Attenuator Independent of Binding Tryptophan and RNA.

Transcription of the tryptophan (trp) operon in Bacillus subtilis is regulated by an attenuation mechanism. Attenuation is controlled by the trpRNA-binding attenuation protein (TRAP). TRAP binds to a site in the 5' leader region of the nascent trp transcript in response to the presence of excess intracellular tryptophan. This binding induces transcription termination upstream of the structural genes of the operon. In prior attenuation models, the role of TRAP was only to alter the secondary structure of the leader region RNA so as to promote formation of the trp attenuator, which was presumed to function as an intrinsic terminator. However, formation of the attenuator alone has been shown to be insufficient to induce efficient termination, indicating that TRAP plays an additional role in this process. To further examine the function of TRAP, we performed a genetic selection for mutant TRAPs that bind tryptophan and RNA but show diminished termination at the trp attenuator. Five such TRAP mutants were obtained. Four of these have substitutions at Glu60, three of which are Lys (E60K) substitutions and the fourth of which is a Val (E60V) substitution. The fifth mutant obtained contains a substitution at Ile63, which is on the same β-strand of TRAP as Glu60. Purified E60K TRAP binds tryptophan and RNA with properties similar to those of the wild type but is defective at inducing termination at the trp attenuator in vitroIMPORTANCE Prior models for attenuation control of the B. subtilis trp operon suggested that the only role for TRAP is to bind to the leader region RNA and alter its folding to induce formation of an intrinsic terminator. However, several recent studies suggested that TRAP plays an additional role in the termination mechanism. We hypothesized that this function could involve residues in TRAP other than those required to bind tryptophan and RNA. Here we obtained TRAP mutants with alterations at Glu60 that are deficient at inducing termination in the leader region while maintaining tryptophan and RNA binding properties similar to those of the WT protein. These studies provide additional evidence that TRAP-mediated transcription termination at the trp attenuator is neither intrinsic nor Rho dependent.

Dynamic Quaternary Associations in Regulating Expression of the B. Subtilis Trp Operon

A large proportion of regulatory proteins are homo-oligomeric, with multiple copies of the same polypeptide assembled into higher-order quaternary structures. In addition to a capacity for both homotropic and heterotropic allostery, homo-oligomeric structures are capable of polyvalent interactions with multiple binding partners, such that different quaternary structures can have differing or opposing functions. The factors that govern the assembly and dissociation of such regulatory supramolecular assemblies are poorly understood, yet critical to their function. We apply a combination of analytical techniques to study the interaction between TRAP and its inhibitor, Anti-TRAP. TRAP (trp RNA-binding attenuation protein) is a symmetric toroidal undecamer (11-mer) that upon being activated by tryptophan (Trp), down-regulates production of the amino acid by sequence specific binding to a single-stranded RNA that is encoded in the 5’ leader of the operon. The inhibitor Anti-TRAP (AT) adopts either toroidal trimeric, or tetrahedral dodecameric, structures in a manner that depends on concentration and pH, while it is the trimeric form of AT that binds Trp-activated TRAP to prevent RNA binding. Using NMR, sedimentation velocity (AUC), SAXS and native mass spectrometry, we have shown that anti-TRAP condenses multiple TRAP oligomers into hetero-complexes, thereby blocking TRAP's RNA-binding sites. Calorimetry, FRET, AUC and native mass spectrometry experiments provide quantitative insights into the activation, assembly, and dissociation of these regulatory complexes, which we find exhibit phase separation behavior in the absence of RNA. These findings and approach may have broad implications for other oligomeric supramolecular regulatory assemblies.

Was the Chlamydial Adaptative Strategy to Tryptophan Starvation an Early Determinant of Plastid Endosymbiosis?

Chlamydiales were recently proposed to have sheltered the future cyanobacterial ancestor of plastids in a common inclusion. The intracellular pathogens are thought to have donated those critical transporters that triggered the efflux of photosynthetic carbon and the consequent onset of symbiosis. Chlamydiales are also suspected to have encoded glycogen metabolism TTS (Type Three Secretion) effectors responsible for photosynthetic carbon assimilation in the eukaryotic cytosol. We now review the reasons underlying other chlamydial lateral gene transfers evidenced in the descendants of plastid endosymbiosis. In particular we show that half of the genes encoding enzymes of tryptophan synthesis in Archaeplastida are of chlamydial origin. Tryptophan concentration is an essential cue triggering two alternative modes of replication in Chlamydiales. In addition, sophisticated tryptophan starvation mechanisms are known to act as antibacterial defenses in animal hosts. We propose that Chlamydiales have donated their tryptophan operon to the emerging plastid to ensure increased synthesis of tryptophan by the plastid ancestor. This would have allowed massive expression of the tryptophan rich chlamydial transporters responsible for symbiosis. It would also have allowed possible export of this valuable amino-acid in the inclusion of the tryptophan hungry pathogens. Free-living single cell cyanobacteria are devoid of proteins able to transport this amino-acid. We therefore investigated the phylogeny of the Tyr/Trp transporters homologous to E. coli TyrP/Mre and found yet another LGT from Chlamydiales to Archaeplastida thereby considerably strengthening our proposal.

NusG Is a Sequence-specific RNA Polymerase Pause Factor That Binds to the Non-template DNA within the Paused Transcription Bubble

NusG, referred to as Spt5 in archaeal and eukaryotic organisms, is the only transcription factor conserved in all three domains of life. This general transcription elongation factor binds to RNA polymerase (RNAP) soon after transcription initiation and dissociation of the RNA polymerase σ factor. Escherichia coli NusG increases transcription processivity by suppressing RNAP pausing, whereas Bacillus subtilis NusG dramatically stimulates pausing at two sites in the untranslated leader of the trpEDCFBA operon. These two regulatory pause sites participate in transcription attenuation and translational control mechanisms, respectively. Here we report that B. subtilis NusG makes sequence-specific contacts with a T-rich sequence in the non-template DNA (ntDNA) strand within the paused transcription bubble. NusG protects T residues of the recognition sequence from permanganate oxidation, and these T residues increase the affinity of NusG to the elongation complex. Binding of NusG to RNAP does not require interaction with RNA. These results indicate that bound NusG prevents forward movement of RNA polymerase by simultaneously contacting RNAP and the ntDNA strand. Mutational studies indicate that amino acid residues of two short regions within the NusG N-terminal domain are primarily responsible for recognition of the trp operon pause signals. Structural modeling indicates that these two regions are adjacent to each another in the protein. We propose that recognition of specific sequences in the ntDNA and stimulation of RNAP pausing is a conserved function of NusG-like transcription factors.

Inter-Protein Sequence Co-Evolution Predicts Known Physical Interactions in Bacterial Ribosomes and the Trp Operon

Interaction between proteins is a fundamental mechanism that underlies virtually all biological processes. Many important interactions are conserved across a large variety of species. The need to maintain interaction leads to a high degree of co-evolution between residues in the interface between partner proteins. The inference of protein-protein interaction networks from the rapidly growing sequence databases is one of the most formidable tasks in systems biology today. We propose here a novel approach based on the Direct-Coupling Analysis of the co-evolution between inter-protein residue pairs. We use ribosomal and trp operon proteins as test cases: For the small resp. large ribosomal subunit our approach predicts protein-interaction partners at a true-positive rate of 70% resp. 90% within the first 10 predictions, with areas of 0.69 resp. 0.81 under the ROC curves for all predictions. In the trp operon, it assigns the two largest interaction scores to the only two interactions experimentally known. On the level of residue interactions we show that for both the small and the large ribosomal subunit our approach predicts interacting residues in the system with a true positive rate of 60% and 85% in the first 20 predictions. We use artificial data to show that the performance of our approach depends crucially on the size of the joint multiple sequence alignments and analyze how many sequences would be necessary for a perfect prediction if the sequences were sampled from the same model that we use for prediction. Given the performance of our approach on the test data we speculate that it can be used to detect new interactions, especially in the light of the rapid growth of available sequence data.

Operon Gene Order Is Optimized for Ordered Protein Complex Assembly.

SummaryThe assembly of heteromeric protein complexes is an inherently stochastic process in which multiple genes are expressed separately into proteins, which must then somehow find each other within the cell. Here, we considered one of the ways by which prokaryotic organisms have attempted to maximize the efficiency of protein complex assembly: the organization of subunit-encoding genes into operons. Using structure-based assembly predictions, we show that operon gene order has been optimized to match the order in which protein subunits assemble. Exceptions to this are almost entirely highly expressed proteins for which assembly is less stochastic and for which precisely ordered translation offers less benefit. Overall, these results show that ordered protein complex assembly pathways are of significant biological importance and represent a major evolutionary constraint on operon gene organization.

Exploring Alternative RNA Structure Sets Using MC-Flashfold and db2cm.

We created an accelerated version of MC-Fold called MC-Flashfold that allows us to compute large numbers of competing secondary structures including noncanonical base pairs. We visualize the base pairs in these sets using high quality intuitive dot plots and arc plots. Our new tools allow us to explore RNA dynamics by visualizing the competing structures in free energy bands. Here we describe how to use these tools to generate dot plots that reveal the postulated anti-terminator stem in the E. coli trp operon leader sequence. These plots show the anti-terminator hairpin loop during transcription and as a minor population of the full-length leader sequence. This is a case of switching RNA structure that had been originally postulated based on short dyad inverted repeats. Other switching RNA sequences can be analyzed by using our method.

The utility of simple mathematical models in understanding gene regulatory dynamics.

In this review, we survey work that has been carried out in the attempts of biomathematicians to understand the dynamic behaviour of simple bacterial operons starting with the initial work of the 1960’s. We concentrate on the simplest of situations, discussing both repressible and inducible systems and then turning to concrete examples related to the biology of the lactose and tryptophan operons. We conclude with a brief discussion of the role of both extrinsic noise and so-called intrinsic noise in the form of translational and/or transcriptional bursting.

A novel strategy to analyze L-tryptophan through allosteric Trp repressor based on rolling circle amplification.

Rolling circle amplification (RCA) has been considered as a powerful tool for nucleic acids detection. Here, a novel repressor-RCA-based method for L-tryptophan (L-Trp) detection was developed. This method utilizes the specific interaction between the RCA circular template and the Trp repressor protein (TrpR) involved in trp operon of Escherichia coli (E. coli). In the absence of L-Trp, the TrpR protein could not bind to the RCA template, and the RCA process can be continued. When L-Trp is present, the activated TrpR will bind to the operon sequence on the RCA template and inhibit the RCA reaction. Thus, the concentration of L-Trp is correlated directly with the fluorescent RCA signals. We succeeded in detecting L-Trp in a single step in simple homogeneous reaction system. The detection limit was estimated to be 0.77 μM (S/N=3) with good linearity. The method can unambiguously distinguish L-Trp from other 19 standard amino acids and L-Trp analogs. This strategy is also promising for detecting many small molecules such as other amino acids and carbohydrates.

Riboswitches: still a lot of undiscovered country.

Riboswitches: still a lot of undiscovered country.

RNA folding retrospective: lessons from ribozymes big and small.

RNA folding retrospective: lessons from ribozymes big and small.

Four RNA families with functional transient structures

Protein-coding and non-coding RNA transcripts perform a wide variety of cellular functions in diverse organisms. Several of their functional roles are expressed and modulated via RNA structure. A given transcript, however, can have more than a single functional RNA structure throughout its life, a fact which has been previously overlooked. Transient RNA structures, for example, are only present during specific time intervals and cellular conditions. We here introduce four RNA families with transient RNA structures that play distinct and diverse functional roles. Moreover, we show that these transient RNA structures are structurally well-defined and evolutionarily conserved. Since Rfam annotates one structure for each family, there is either no annotation for these transient structures or no such family. Thus, our alignments either significantly update and extend the existing Rfam families or introduce a new RNA family to Rfam. For each of the four RNA families, we compile a multiple-sequence alignment based on experimentally verified transient and dominant (dominant in terms of either the thermodynamic stability and/or attention received so far) RNA secondary structures using a combination of automated search via covariance model and manual curation. The first alignment is the Trp operon leader which regulates the operon transcription in response to tryptophan abundance through alternative structures. The second alignment is the HDV ribozyme which we extend to the 5′ flanking sequence. This flanking sequence is involved in the regulation of the transcript's self-cleavage activity. The third alignment is the 5′ UTR of the maturation protein from Levivirus which contains a transient structure that temporarily postpones the formation of the final inhibitory structure to allow translation of maturation protein. The fourth and last alignment is the SAM riboswitch which regulates the downstream gene expression by assuming alternative structures upon binding of SAM. All transient and dominant structures are mapped to our new alignments introduced here.

Teaching the Big Ideas of Biology with Operon Models

This paper presents an activity that engages students in model-based reasoning, requiring them to predict the behavior of the trp and lac operons under different environmental conditions. Students are presented six scenarios for the trp operon and five for the lac operon. In most of the scenarios, specific mutations have occurred in genetic elements of the system that alter the behavior from the norm. Students are also challenged to relate their understanding of operon behavior to the “Big Ideas” of homeostasis, evolution, information, interactions, and emergent properties. By using operons to teach students to reason with models of complex systems and understand broad themes, we equip them with powerful skills and ideas that form a solid foundation for their future learning in biology.

Characterization of TRAP-mediated regulation of the B. subtilis trp operon using in vitro transcription and transcriptional reporter fusions in vivo.

In Bacillus subtilis, transcription of the tryptophan biosynthetic operon is regulated by an attenuation mechanism involving two alternative RNA secondary structures in the 5' leader region upstream of the structural genes. Regulation is accomplished, at least in part, by controlling which RNA structure forms during transcription of the operon. When intracellular tryptophan levels are high, the trp RNA-binding attenuation protein (TRAP) binds to the nascent trp mRNA to promote formation of a transcription terminator structure so as to induce transcription termination prior to the structural genes. In limiting tryptophan, TRAP does not bind, the alternative antiterminator RNA structure forms, and the operon is transcribed. Several in vitro and in vivo assays have been utilized to study TRAP-mediated regulation of both transcription and translation. Here, we describe using in vitro transcription attenuation assays and in vivo trp-lacZ fusions to examine TRAP-mediated regulation of the trp genes.