Alanine-scanning mutagenesis of Bacillus subtilis trp RNA-binding attenuation protein (TRAP) reveals residues involved in tryptophan binding and RNA binding

Riboregulation in bacteria: From general principles to novel mechanisms of the trp attenuator and its sRNA and peptide products

Gene expression strategies ensuring bacterial survival and competitiveness rely on cis- and trans-acting RNA-regulators (riboregulators). Among the cis-acting riboregulators are transcriptional and translational attenuators, and antisense RNAs (asRNAs). The trans-acting riboregulators are small RNAs (sRNAs) that bind proteins or base pairs with other RNAs. This classification is artificial since some regulatory RNAs act both in cis and in trans, or function in addition as small mRNAs. A prominent example is the archetypical, ribosome-dependent attenuator of tryptophan (Trp) biosynthesis genes. It responds by transcription attenuation to two signals, Trp availability and inhibition of translation, and gives rise to two trans-acting products, the attenuator sRNA rnTrpL and the leader peptide peTrpL. In Escherichia coli, rnTrpL links Trp availability to initiation of chromosome replication and in Sinorhizobium meliloti, it coordinates regulation of split tryptophan biosynthesis operons. Furthermore, in S. meliloti, peTrpL is involved in mRNA destabilization in response to antibiotic exposure. It forms two types of asRNA-containing, antibiotic-dependent ribonucleoprotein complexes (ARNPs), one of them changing the target specificity of rnTrpL. The posttranscriptional role of peTrpL indicates two emerging paradigms: (1) sRNA reprograming by small molecules and (2) direct involvement of antibiotics in regulatory RNPs. They broaden our view on RNA-based mechanisms and may inspire new approaches for studying, detecting, and using antibacterial compounds. This article is categorized under: RNA Interactions with Proteins and Other Molecules > Small Molecule-RNA Interactions RNA Interactions with Proteins and Other Molecules > RNA-Protein Complexes Regulatory RNAs/RNAi/Riboswitches > Regulatory RNAs.

Population Distributions from Native Mass Spectrometry Titrations Reveal Nearest-Neighbor Cooperativity in the Ring-Shaped Oligomeric Protein TRAP

Allostery pervades macromolecular function and drives cooperative binding of ligands to macromolecules. To decipher the mechanisms of cooperative ligand binding, it is necessary to define, at a microscopic level, the thermodynamic consequences of binding of each ligand to its energetically coupled site(s). However, extracting these microscopic constants is difficult for macromolecules with more than two binding sites, because the observable [e.g., nuclear magnetic resonance (NMR) chemical shift changes, fluorescence, and enthalpy] can be altered by allostery, thereby distorting its proportionality to site occupancy. Native mass spectrometry (MS) can directly quantify the populations of homo-oligomeric protein species with different numbers of bound ligands, provided the populations are proportional to ion counts and that MS-compatible electrolytes do not alter the overall thermodynamics. These measurements can help decipher allosteric mechanisms by providing unparalleled access to the statistical thermodynamic partition function. We used native MS (nMS) to study the cooperative binding of tryptophan (Trp) to Bacillus stearothermophilus trp RNA binding attenuation protein (TRAP), a ring-shaped homo-oligomeric protein complex with 11 identical binding sites. MS-compatible solutions did not significantly perturb protein structure or thermodynamics as assessed by isothermal titration calorimetry and NMR spectroscopy. Populations of Trpn-TRAP11 states were quantified as a function of Trp concentration by nMS. The population distributions could not be explained by a noncooperative binding model but were described well by a mechanistic nearest-neighbor cooperative model. Nonlinear least-squares fitting yielded microscopic thermodynamic constants that define the interactions between neighboring binding sites. This approach may be applied to quantify thermodynamic cooperativity in other ring-shaped proteins.

Regulation of Bacterial Gene Expression by Transcription Attenuation

A wide variety of mechanisms that control gene expression in bacteria are based on conditional transcription termination. Generally, in these mechanisms, a transcription terminator is located between a promoter and a downstream gene(s), and the efficiency of the terminator is controlled by a regulatory effector that can be a metabolite, protein, or RNA. The most common type of regulation involving conditional termination is transcription attenuation, in which the primary regulatory target is an essential element of a single terminator. The terminator can be either intrinsic or Rho dependent, with each presenting unique regulatory targets. Transcription attenuation mechanisms can be divided into five classes based primarily on the manner in which transcription termination is rendered conditional. This review summarizes each class of control mechanisms from a historical perspective, describes important examples in a physiological context and the current state of knowledge, highlights major advances, and discusses expectations of future discoveries.

Computational identification of binding energy hot spots in protein-RNA complexes using an ensemble approach

Motivation

Identifying RNA-binding residues, especially energetically favored hot spots, can provide valuable clues for understanding the mechanisms and functional importance of protein-RNA interactions. Yet, limited availability of experimentally recognized energy hot spots in protein-RNA crystal structures leads to the difficulties in developing empirical identification approaches. Computational prediction of RNA-binding hot spot residues is still in its infant stage.

Results

Here, we describe a computational method, PrabHot (Prediction of protein-RNA binding hot spots), that can effectively detect hot spot residues on protein-RNA binding interfaces using an ensemble of conceptually different machine learning classifiers. Residue interaction network features and new solvent exposure characteristics are combined together and selected for classification with the Boruta algorithm. In particular, two new reference datasets (benchmark and independent) have been generated containing 107 hot spots from 47 known protein-RNA complex structures. In 10-fold cross-validation on the training dataset, PrabHot achieves promising performances with an AUC score of 0.86 and a sensitivity of 0.78, which are significantly better than that of the pioneer RNA-binding hot spot prediction method HotSPRing. We also demonstrate the capability of our proposed method on the independent test dataset and gain a competitive advantage as a result.

Availability and implementation

The PrabHot webserver is freely available at http://denglab.org/PrabHot/.

Contact

leideng@csu.edu.cn.

Supplementary information

Supplementary data are available at Bioinformatics online.

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.

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.

Modulating TRAP-mediated transcription termination by AT during transcription of the leader region of the Bacillus subtilis trp operon

An 11-subunit protein called trpRNA binding Attenuation Protein (TRAP) controls attenuation of the tryptophan biosynthetic (trpEDCFBA) operon in Bacillus subtilis. Tryptophan-activated TRAP binds to 11 (G/U)AG repeats in the 5′ leader region of trp mRNAs, and downregulates expression of the operon by promoting transcription termination prior to the structural genes. Anti-TRAP (AT) is an antagonist that binds to tryptophan-activated TRAP and prevents TRAP from binding to RNA, thereby upregulating expression of the trp genes. AT forms trimers, and multiple trimers bind to a TRAP 11mer. It is not known how many trimers must bind to TRAP in order to interfere with RNA binding. Studies of isolated TRAP and AT showed that AT can prevent TRAP from binding to the trp leader RNA but cannot dissociate a pre-formed TRAP-RNA complex. Here, we show that AT can prevent TRAP-mediated termination of transcription by inducing dissociation of TRAP from the nascent RNA when it has bound to fewer than all 11 (G/U)AG repeats. The 5′-most region of the TRAP binding site in the nascent transcript is most susceptible to dissociation from TRAP. We also show that one AT trimer bound to TRAP 11mer reduces the affinity of TRAP for RNA and eliminates TRAP-mediated transcription termination in vitro.

The Bacillus subtilis TRAP protein can induce transcription termination in the leader region of the tryptophan biosynthetic (trp) operon independent of the trp attenuator RNA

In Bacillus subtilis, transcription of the tryptophan biosynthetic operon is regulated by an attenuation mechanism. When intracellular tryptophan levels are high, the TRAP protein binds to the 5′ leader region of the nascent trp mRNA and induces transcription termination prior to the structural genes. In limiting tryptophan, TRAP does not bind and the operon is transcribed. Two competing RNA secondary structures termed the antiterminator and terminator (attenuator) can form in the leader region RNA. In prior attenuation models, the only role of TRAP binding was to alter the RNA secondary structure to allow formation of the attenuator, which has been thought function as an intrinsic transcription terminator. However, recent studies have shown that the attenuator is not an effective intrinsic terminator. From these studies it was not clear whether TRAP functions independently or requires the presence of the attenuator RNA structure. Hence we have further examined the role of the attenuator RNA in TRAP-mediated transcription termination. TRAP was found to cause efficient transcription termination in the trp leader region in vivo when the attenuator was mutated or deleted. However, TRAP failed to induce transcription termination at these mutant attenuators in a minimal in vitro transcription system with B. subtilis RNA polymerase. Further studies using this system showed that NusA as well as the timing of TRAP binding to RNA play a role in the observed differences in vivo and in vitro.

Homotropic cooperativity from the activation pathway of the allosteric ligand-responsive regulatory trp RNA-binding attenuation protein

The trp RNA-binding attenuation protein (TRAP) assembles into an 11-fold symmetric ring that regulates transcription and translation of trp-mRNA in bacilli via heterotropic allosteric activation by the amino acid tryptophan (Trp). Whereas nuclear magnetic resonance studies have revealed that Trp-induced activation coincides with both microsecond to millisecond rigidification and local structural changes in TRAP, the pathway of binding of the 11 Trp ligands to the TRAP ring remains unclear. Moreover, because each of 11 bound Trp molecules is completely surrounded by protein, its release requires flexibility of Trp-bound (holo) TRAP. Here, we used stopped-flow fluorescence to study the kinetics of Trp binding by Bacillus stearothermophilus TRAP over a range of temperatures and observed well-separated kinetic steps. These data were analyzed using nonlinear least-squares fitting of several two- and three-step models. We found that a model with two binding steps best describes the data, although the structural equivalence of the binding sites in TRAP implies a fundamental change in the time-dependent structure of the TRAP rings upon Trp binding. Application of the two-binding step model reveals that Trp binding is much slower than the diffusion limit, suggesting a gating mechanism that depends on the dynamics of apo TRAP. These data also reveal that dissociation of Trp from the second binding mode is much slower than after the first Trp binding mode, revealing insight into the mechanism for positive homotropic allostery, or cooperativity. Temperature-dependent analyses reveal that both binding modes imbue increases in bondedness and order toward a more compressed active state. These results provide insight into mechanisms of cooperative TRAP activation and underscore the importance of protein dynamics for ligand binding, ligand release, protein activation, and allostery.

Gel mobility shift assays to detect protein-RNA interactions

The gel mobility shift assay is a powerful technique for detecting and quantifying protein-RNA interactions. While other techniques such as filter binding and isothermal titration calorimetry (ITC) are available for quantifying protein-RNA interactions, gel shift analysis provides the added advantage that you can visualize the protein-RNA complexes. In the gel shift assay, protein-RNA complexes are typically separated from the unbound RNA using native polyacrylamide gels in Tris/borate/EDTA buffer, although an alternative Tris-glycine buffering system is superior in many situations. Here, we describe both gel shift methods, along with strategies to improve separation of protein-RNA complexes from free RNA, which can be a particular challenge for small RNA binding proteins.

Mechanisms of allosteric gene regulation by NMR quantification of microsecond-millisecond protein dynamics

The trp RNA-binding attenuation protein (TRAP) is a paradigmatic allosteric protein that regulates the tryptophan biosynthetic genes associated with the trp operon in bacilli. The ring-shaped 11-mer TRAP is activated for recognition of a specific trp-mRNA target by binding up to 11 tryptophan molecules. To characterize the mechanisms of tryptophan-induced TRAP activation, we have performed methyl relaxation dispersion (MRD) nuclear magnetic resonance (NMR) experiments that probe the time-dependent structure of TRAP in the microsecond-to-millisecond "chemical exchange" time window. We find significant side chain flexibility localized to the RNA and tryptophan binding sites of the apo protein and that these dynamics are dramatically reduced upon ligand binding. Analysis of the MRD NMR data provides insights into the structural nature of transiently populated conformations sampled in solution by apo TRAP. The MRD data are inconsistent with global two-state exchange, indicating that conformational sampling in apo TRAP is asynchronous. These findings imply a temporally heterogeneous population of structures that are incompatible with RNA binding and substantiate the study of TRAP as a paradigm for probing and understanding essential dynamics in allosteric, regulatory proteins.

Mechanism of NusG-stimulated pausing, hairpin-dependent pause site selection and intrinsic termination at overlapping pause and termination sites in the Bacillus subtilis trp leader

The Bacillus subtilis trpEDCFBA operon is regulated by TRAP-dependent transcription attenuation and translation repression mechanisms. Previous results showed that NusA and NusG cooperatively stimulate RNA polymerase pausing at U107 and U144 in the trp leader, and that NusG is required for pausing at U144 in vivo. Pausing at U107 and U144 participate in the attenuation and translation repression mechanisms, respectively, by providing additional time for TRAP binding. The intrinsic trp leader terminator overlaps the hairpin-dependent U144 pause site. Here, we conducted a systematic mutational analysis of the terminator/pause region. Deletion of the hairpin reduced pausing but did not affect pause site selection. Thus, hairpin-stimulated pausing is a more appropriate term than hairpin-dependent pausing for this pause site. In contrast, minor changes to the hairpin abolished termination. Sequences in the U-rich/T-rich tract following the hairpin affected termination and pausing differentially. The distance between the hairpin and the 3' end of the RNA dictates the position of termination, whereas the sequence downstream from the hairpin is responsible for pause site selection. NusA was found to increase both pausing and termination by reducing the rate of transcription. We also found that NusG-stimulated pausing is sequence specific and that NusG does not affect termination.

Regulation of translation initiation by RNA binding proteins

RNA binding proteins are capable of regulating translation initiation by a variety of mechanisms. Although the vast majority of these regulatory mechanisms involve translational repression, one example of translational activation has been characterized in detail. The RNA recognition targets of these regulatory proteins exhibit a wide range in structural complexity, with some proteins recognizing complex pseudoknot structures and others binding to simple RNA hairpins and/or short repeated single-stranded sequences. In some instances the bound protein directly competes with ribosome binding, and in other instances the bound protein promotes formation of an RNA structure that inhibits ribosome binding. Examples also exist in which the bound protein traps the ribosome in a complex that is incapable of initiating translation.

The nature of the TRAP-Anti-TRAP complex

Tryptophan biosynthesis is subject to exquisite control in species of Bacillus and has become one of the best-studied model systems in gene regulation. The protein TRAP (trp RNA-binding attenuation protein) predominantly forms a ring-shaped 11-mer, which binds cognate RNA in the presence of tryptophan to suppress expression of the trp operon. TRAP is itself regulated by the protein Anti-TRAP, which binds to TRAP and prevents RNA binding. To date, the nature of this interaction has proved elusive. Here, we describe mass spectrometry and analytical centrifugation studies of the complex, and 2 crystal structures of the TRAP-Anti-TRAP complex. These crystal structures, both refined to 3.2-A resolution, show that Anti-TRAP binds to TRAP as a trimer, sterically blocking RNA binding. Mass spectrometry shows that 11-mer TRAP may bind up to 5 AT trimers, and an artificial 12-mer TRAP may bind 6. Both forms of TRAP make the same interactions with Anti-TRAP. Crystallization of wild-type TRAP with Anti-TRAP selectively pulls the 12-mer TRAP form out of solution, so the crystal structure of wild-type TRAP-Anti-TRAP complex reflects a minor species from a mixed population.

Molecular basis of TRAP-5'SL RNA interaction in the Bacillus subtilis trp operon transcription attenuation mechanism

Expression of the Bacillus subtilis trpEDCFBA operon is regulated by the interaction of tryptophan-activated TRAP with 11 (G/U)AG trinucleotide repeats that lie in the leader region of the nascent trp transcript. Bound TRAP prevents folding of an antiterminator structure and favors formation of an overlapping intrinsic terminator hairpin upstream of the trp operon structural genes. A 5'-stem-loop (5'SL) structure that forms just upstream of the triplet repeat region increases the affinity of TRAP-trp RNA interaction, thereby increasing the efficiency of transcription termination. Single-stranded nucleotides in the internal loop and in the hairpin loop of the 5'SL are important for TRAP binding. We show here that altering the distance between these two loops suggests that G7, A8, and A9 from the internal loop and A19 and G20 from the hairpin loop constitute two structurally discrete TRAP-binding regions. Photochemical cross-linking experiments also show that the hairpin loop of the 5'SL is in close proximity to the flexible loop region of TRAP during TRAP-5'SL interaction. The dimensions of B. subtilis TRAP and of a three-dimensional model of the 5'SL generated using the MC-Sym and MC-Fold pipeline imply that the 5'SL binds the protein in an orientation where the helical axis of the 5'SL is perpendicular to the plane of TRAP. This interaction not only increases the affinity of TRAP-trp leader RNA interaction, but also orients the downstream triplet repeats for interaction with the 11 KKR motifs that lie on TRAP's perimeter, increasing the likelihood that TRAP will bind in time to promote termination.

The structure of YqeH. An AtNOS1/AtNOA1 ortholog that couples GTP hydrolysis to molecular recognition

AtNOS1/AtNOA1 was identified as a nitric oxide-generating enzyme in plants, but that function has recently been questioned. To resolve issues surrounding AtNOA1 activity, we report the biochemical properties and a 2.36 A resolution crystal structure of a bacterial AtNOA1 ortholog (YqeH). Geobacillus YqeH fused to a putative AtNOA1 leader peptide complements growth and morphological defects of Atnoa1 mutant plants. YqeH does not synthesize nitric oxide from L-arginine but rather hydrolyzes GTP. The YqeH structure reveals a circularly permuted GTPase domain and an unusual C-terminal beta-domain. A small N-terminal domain, disordered in the structure, binds zinc. Structural homology among the C-terminal domain, the RNA-binding regulator TRAP, and the hypoxia factor pVHL define a recognition module for peptides and nucleic acids. TRAP residues important for RNA binding are conserved by the YqeH C-terminal domain, whose positioning is coupled to GTP hydrolysis. YqeH and AtNOA1 probably act as G-proteins that regulate nucleic acid recognition and not as nitric-oxide synthases.

AtNOS/AtNOA1 is a functional Arabidopsis thaliana cGTPase and not a nitric-oxide synthase

AtNOS1 was previously identified as a potential nitric-oxide synthase (NOS) in Arabidopsis thaliana, despite lack of sequence similarity to animal NOSs. Although the dwarf and yellowish leaf phenotype of Atnos1 knock-out mutant plants can be rescued by treatment with exogenous NO, doubts have recently been raised as to whether AtNOS1 is a true NOS. Moreover, depending on the type of physiological responses studied, Atnos1 is not always deficient in NO induction and/or detection, as previously reported. Here, we present experimental evidence showing that AtNOS1 is unable to bind and oxidize arginine to NO. These results support the argument that AtNOS1 is not a NOS. We also show that the renamed NO-associated protein 1 (AtNOA1) is a member of the circularly permuted GTPase family (cGTPase). AtNOA1 specifically binds GTP and hydrolyzes it. Complementation experiments of Atnoa1 mutant plants with different constructs of AtNOA1 show that GTP hydrolysis is necessary but not sufficient for the physiological function of AtNOA1. Mutant AtNOA1 lacking the C-terminal domain, although retaining GTPase activity, failed to complement Atnoa1, suggesting that this domain plays a crucial role in planta. cGTPases appear to be RNA-binding proteins, and the closest homolog of AtNOA1, the Bacillus subtilis YqeH, has been shown to participate in ribosome assembly and stability. We propose a similar function for AtNOA1 and discuss it in the light of its potential role in NO accumulation and plant development.

Insights into activation and RNA binding of trp RNA-binding attenuation protein (TRAP) through all-atom simulations

Tryptophan biosynthesis in Bacillus stearothermophilus is regulated by a trp RNA binding attenuation protein (TRAP). It is a ring-shaped 11-mer of identical 74 residue subunits. Tryptophan binding pockets are located between adjacent subunits, and tryptophan binding activates TRAP to bind RNA. Here, we report results from all-atom molecular dynamics simulations of the system, complementing existing extensive experimental studies. We focus on two questions. First, we look at the activation mechanism, of which relatively little is known experimentally. We find that the absence of tryptophan allows larger motions close to the tryptophan binding site, and we see indication of a conformational change in the BC loop. However, complete deactivation seems to occur on much longer time scales than the 40 ns studied here. Second, we study the TRAP-RNA interactions. We look at the relative flexibilities of the different bases in the complex and analyze the hydrogen bonds between the protein and RNA. We also study the role of Lys37, Lys56, and Arg58, which have been experimentally identified as essential for RNA binding. Hydrophobic stacking of Lys37 with the nearby RNA base is confirmed, but we do not see direct hydrogen bonding between RNA and the other two residues, in contrast to the crystal structure. Rather, these residues seem to stabilize the RNA-binding surface, and their positive charge may also play a role in RNA binding. Simulations also indicate that TRAP is able to attract RNA nonspecifically, and the interactions are quantified in more detail using binding energy calculations. The formation of the final binding complex is a very slow process: within the simulation time scale of 40 ns, only two guanine bases become bound (and no others), indicating that the binding initiates at these positions. In general, our results are in good agreement with experimental studies, and provide atomic-scale insights into the processes.

Intersubunit linker length as a modifier of protein stability: crystal structures and thermostability of mutant TRAP

The ability of proteins to self-assemble into complex, functional nanoscale structures is expected to become of significant use in the manufacture of artificial nanodevices with a wide range of novel applications. The bacterial protein TRAP has potential uses as a nanoscale component as it is ring-shaped, with a central, modifiable cavity. Furthermore, it can be engineered to make a ring of 12-fold symmetry, which is advantageous for packing into two-dimensional arrays. The 12mer form of TRAP is made by linking multiple subunits together on the same polypeptide, but the usefulness of the 12mers described to date is limited by their poor stability. Here we show that, by altering the length of the peptide linker between subunits, the thermostability can be significantly improved. Since the subunit interfaces of the different 12mers are essentially identical, stabilization arises from the reduction of strain in the linkers. Such a simple method of controlling the stability of modular proteins may have wide applications, and demonstrates the lack of absolute correlation between interactions observable by crystallography and the internal energy of a complex.

Alanine scanning mutagenesis of anti-TRAP (AT) reveals residues involved in binding to TRAP

The trp RNA-binding attenuation protein (TRAP) regulates expression of the tryptophan biosynthetic (trp) genes in response to changes in intracellular levels of free l-tryptophan in many Gram-positive bacteria. When activated by binding tryptophan, TRAP binds to the mRNAs of several genes involved in tryptophan metabolism, and down-regulates transcription or translation of these genes. Anti-TRAP (AT) is an antagonist of TRAP that binds to tryptophan-activated TRAP and prevents it from binding to its RNA targets, and thereby up-regulates trp gene expression. The crystal structure shows that AT is a cone-shaped trimer (AT(3)) with the N-terminal residues of the three subunits assembled at the apex of the cone and that these trimers can further assemble into a dodecameric (AT(12)) structure. Using alanine-scanning mutagenesis we found four residues, all located on the "top" region of AT(3), that are essential for binding to TRAP. Fluorescent labeling experiments further suggest that the top region of AT is in close juxtaposition to TRAP in the AT-TRAP complex. In vivo studies confirmed the importance of these residues on the top of AT in regulating TRAP mediated gene regulation.

TRAP-5' stem loop interaction increases the efficiency of transcription termination in the Bacillus subtilis trpEDCFBA operon leader region

TRAP regulates expression of the Bacillus subtilis trpEDCFBA operon by a transcription attenuation mechanism in which tryptophan-activated TRAP binds to 11 (G/U)AG repeats in the nascent trp leader transcript. Bound TRAP blocks formation of an antiterminator structure and allows formation of an overlapping intrinsic terminator upstream of the trp operon structural genes. A 5' stem-loop (5'SL) structure located upstream of the triplet repeat region also interacts with TRAP. TRAP-5'SL RNA interaction participates in the transcription attenuation mechanism by preferentially increasing the affinity of TRAP for the nascent trp leader transcript during the early stages of transcription, when only a few triplet repeats have been synthesized. Footprinting assays indicated that the 5'SL contacts TRAP through two discrete groups of single-stranded nucleotides that lie in the hairpin loop and in an internal loop. Filter binding and in vivo expression assays of 5'SL mutants established that G7, A8, and A9 from the internal loop, and A19 and G20 from the hairpin loop are critical for proper 5'SL function. These nucleotides are conserved among certain other 5'SL-containing organisms. Single-round transcription results indicated that the 5'SL increases the termination efficiency when transcription is fast; however, the influence of the 5'SL was lost when transcription was slowed by reducing the ribonucleoside triphosphate concentration. Since there is a limited amount of time for TRAP to bind to the nascent transcript and promote termination, our data suggest that the contribution of TRAP-5'SL interaction increases the rate of TRAP binding, which, in turn, increases the efficiency of transcription termination.

Dynamic Allostery in the Ring Protein TRAP

We have discovered distinct, characteristic differences in the thermodynamic signatures of tryptophan binding by trp RNA-binding attenuation protein (TRAP) from two different bacterial species. The TRAP 11mer ring binds 11 molecules of tryptophan at symmetry-related sites. Tryptophan binding to Bacillus stearothermophilus TRAP is not cooperative, but isothermal titration calorimetry shows that filling the first tryptophan binding sites of Bacillus subtilis TRAP has a marked effect on the thermodynamics of subsequent ligand binding. We have identified a single, conservative amino acid replacement (Ile to Leu) in B. subtilis TRAP that abolishes this effect, and suggest the initial ligand binding causes a change throughout the wild-type protein ring.

The rate of TRAP binding to RNA is crucial for transcription attenuation control of the B. subtilis trp operon

The trp RNA-binding attenuation protein (TRAP) regulates expression of the tryptophan biosynthetic and transport genes in Bacillus subtilis in response to changes in the levels of intracellular tryptophan. Transcription of the trpEDCFBA operon is controlled by an attenuation mechanism involving two overlapping RNA secondary structures in the 5' leader region of the trp transcript; TRAP binding promotes formation of a transcription terminator structure that halts transcription prior to the structural genes. TRAP consists of 11 identical subunits and is activated to bind RNA by binding up to 11 molecules of L-tryptophan. The TRAP binding site in the leader region of the trp operon mRNA consists of 11 (G/U)AG repeats. We examined the importance of the rate of TRAP binding to RNA for the transcription attenuation mechanism. We compared the properties of two types of TRAP 11-mers: homo-11-mers composed of 11 wild-type subunits, and hetero-11-mers with only one wild-type subunit and ten mutant subunits defective in binding either RNA or tryptophan. The hetero-11-mers bound RNA with only slightly diminished equilibrium binding affinity but with slower on-rates as compared to WT TRAP. The hetero-11-mers showed significantly decreased ability to induce transcription termination in the trp leader region when examined using an in vitro attenuation system. Together these results indicate that the rate of TRAP binding to RNA is a crucial factor in TRAP's ability to control attenuation.

The trp RNA-binding attenuation protein (TRAP) of Bacillus subtilis regulates translation initiation of ycbK, a gene encoding a putative efflux protein, by blocking ribosome binding

Expression of the Bacillus subtilis tryptophan biosynthetic genes trpEDCFBA and trpG, as well as a putative tryptophan transport gene (trpP), are regulated in response to tryptophan by the trp RNA-binding attenuation protein (TRAP). TRAP regulates expression of these genes by transcription attenuation and translation control mechanisms. Here we show that TRAP also regulates translation of ycbK, a gene that encodes a protein with similarities to known efflux proteins. As a likely TRAP-binding site consisting of 11 NAG repeats overlaps the ycbK translation initiation region, experiments were carried out to determine whether TRAP regulates translation of ycbK. TRAP was observed to regulate expression of a ycbK'-'lacZ translational fusion 20-fold in response to tryptophan. Binding studies indicated that TRAP binds to the ycbK transcript with high affinity and specificity. Footprint studies revealed that the central seven triplet repeats were protected by bound TRAP, while toeprint results suggest that nine triplet repeats contribute to TRAP binding. Additional toeprint and in vitro translation analyses demonstrated that bound TRAP regulates YcbK synthesis by blocking ribosome binding. We also identified two dipeptide coding minigenes between the Shine-Dalgarno sequence and start codon of ycbK. Expression of one of the minigenes modestly interfered with translation of ycbK.

Translation control of trpG from transcripts originating from the folate operon promoter of Bacillus subtilis is influenced by translation-mediated displacement of bound TRAP, while translation control of transcripts originating from a newly identified trpG promoter is not

Bacillus subtilis trpG encodes a glutamine amidotransferase subunit that participates in the biosynthesis of both tryptophan and folic acid. TRAP inhibits translation of trpG in response to tryptophan by binding to a site that overlaps the trpG Shine-Dalgarno sequence, thereby blocking ribosome binding. Similar mechanisms regulate trpP and ycbK translation. The equilibrium binding constants of tryptophan-activated TRAP for the trpG, ycbK, and trpP transcripts were determined to be 8, 3, and 50 nM, respectively. Despite TRAP having a higher affinity for the trpG transcript, TRAP exhibited the least control of trpG expression. The trpG Shine-Dalgarno sequence overlaps the stop codon of the upstream pabB gene, while six of nine triplet repeats within the TRAP binding site are located upstream of the pabB stop codon. Thus, ribosomes translating the upstream pabB cistron could be capable of reducing TRAP-dependent control of TrpG synthesis by displacing bound TRAP. Expression studies using pabB-trpG'-'lacZ fusions in the presence or absence of an engineered stop codon within pabB suggest that translation-mediated displacement of bound TRAP reduces TRAP-dependent inhibition of TrpG synthesis from transcripts originating from the folate operon promoter (P(pabB)). A new trpG promoter (P(trpG)) was identified in the pabB coding sequence that makes a larger contribution to trpG expression than does P(pabB). We found that TRAP-dependent regulation of trpG expression is more extensive for a transcript originating from P(trpG) and that transcripts originating from P(trpG) are not subject to translation-mediated displacement of bound TRAP.

Different modes and potencies of translational repression by sequence-specific RNA-protein interaction at the 5'-UTR

To determine whether sequence-specific RNA–protein interaction at the 5′-untranslated region (5′-UTR) can potently repress translation in mammalian cells, a bicistronic translational repression assay was developed to permit direct assessment of RNA–protein interaction and translational repression in transiently transfected living mammalian cells. Changes in cap-dependent yellow fluorescent protein (YFP) and internal ribosome entry sequence (IRES)-dependent cyan fluorescent protein (CFP) translation were monitored by fluorescence microscopy. Selective repression of YFP or coordinate repression of both YFP and CFP translation occurred, indicating two distinct modes by which RNA-binding proteins repress translation through the 5′-UTR. Interestingly, a single-stranded RNA-binding protein from Bacillus subtilis, tryptophan RNA-binding attenuation protein (TRAP), showed potent translational repression, dependent on the level of TRAP expression and position of its cognate binding site within the bicistronic reporter transcript. As the first of its class to be examined in mammalian cells, its potency in repression of translation through the 5′-UTR may be a general feature for this class of single-stranded RNA-binding proteins. Finally, a one-hybrid screen based on translational repression through the 5′-UTR identified linkers supporting full-translational repression as well as a range of partial repression by TRAP within the context of a fusion protein.

Thermodynamics of tryptophan-mediated activation of the trp RNA-binding attenuation protein

The trp RNA-binding attenuation protein (TRAP) functions in many bacilli to control the expression of the tryptophan biosynthesis genes. Transcription of the trp operon is controlled by TRAP through an attenuation mechanism, in which competition between two alternative secondary-structural elements in the 5' leader sequence of the nascent mRNA is influenced by tryptophan-dependent binding of TRAP to the RNA. Previously, NMR studies of the undecamer (11-mer) suggested that tryptophan-dependent control of RNA binding by TRAP is accomplished through ligand-induced changes in protein dynamics. We now present further insights into this ligand-coupled event from hydrogen/deuterium (H/D) exchange analysis, differential scanning calorimetry (DSC), and isothermal titration calorimetry (ITC). Scanning calorimetry showed tryptophan dissociation to be independent of global protein unfolding, while analysis of the temperature dependence of the binding enthalpy by ITC revealed a negative heat capacity change larger than expected from surface burial, a hallmark of binding-coupled processes. Analysis of this excess heat capacity change using parameters derived from protein folding studies corresponds to the ordering of 17-24 residues per monomer of TRAP upon tryptophan binding. This result is in agreement with qualitative analysis of residue-specific broadening observed in TROSY NMR spectra of the 91 kDa oligomer. Implications for the mechanism of ligand-mediated TRAP activation through a shift in a preexisting conformational equilibrium and an induced-fit conformational change are discussed.

Substitutions of Thr30 provide mechanistic insight into tryptophan-mediated activation of TRAP binding to RNA

TRAP is an 11 subunit RNA binding protein that regulates expression of genes involved in tryptophan biosynthesis and transport in Bacillus subtilis. TRAP is activated to bind RNA by binding up to 11 molecules of l-tryptophan in pockets formed by adjacent subunits. The precise mechanism by which tryptophan binding activates TRAP is not known. Thr30 is in the tryptophan binding pocket. A TRAP mutant in which Thr30 is substituted with Val (T30V) does not bind tryptophan but binds RNA constitutively, suggesting that Thr30 plays a key role in the activation mechanism. We have examined the effects of other substitutions of Thr30. TRAP proteins with small beta-branched aliphatic side chains at residue 30 bind RNA constitutively, whereas those with a small polar side chain show tryptophan-dependent RNA binding. Several mutant proteins exhibited constitutive RNA binding that was enhanced by tryptophan. Although the tryptophan and RNA binding sites on TRAP are distinct and are separated by approximately 7.5 A, several substitutions of residues that interact with the bound RNA restored tryptophan binding to T30V TRAP. These observations support the hypothesis that conformational changes in TRAP relay information between the tryptophan and RNA binding sites of the protein.

Complexity in regulation of tryptophan biosynthesis in Bacillus subtilis

Bacillus subtilis uses novel regulatory mechanisms in controlling expression of its genes of tryptophan synthesis and transport. These mechanisms respond to changes in the intracellular concentrations of free tryptophan and uncharged tRNA(Trp). The major B. subtilis protein that regulates tryptophan biosynthesis is the tryptophan-activated RNA-binding attenuation protein, TRAP. TRAP is a ring-shaped molecule composed of 11 identical subunits. Active TRAP binds to unique RNA segments containing multiple trinucleotide (NAG) repeats. Binding regulates both transcription termination and translation in the trp operon, and translation of other coding regions relevant to tryptophan metabolism. When there is a deficiency of charged tRNA(Trp), B. subtilis forms an anti-TRAP protein, AT. AT antagonizes TRAP function, thereby increasing expression of all the genes regulated by TRAP. Thus B. subtilis and Escherichia coli respond to identical regulatory signals, tryptophan and uncharged tRNA(Trp), yet they employ different mechanisms in regulating trp gene expression.

Bacillus subtilis TRAP binds to its RNA target by a 5' to 3' directional mechanism

TRAP is an 11 subunit RNA-binding protein that regulates expression of the Bacillus subtilis trpEDCFBA operon by transcription attenuation and translation control mechanisms. Tryptophan-activated TRAP acts by binding to a site in the 5'-untranslated leader region of trp mRNA consisting of 11 (G/U)AG repeats. We used mung bean nuclease footprinting to analyze the interaction of TRAP with several artificial binding sites composed of 11 GAG repeats in nucleic acids that lack secondary structure. Affinities for individual repeats within a binding site did not vary significantly. In contrast, the association rate constants were highest for repeats at the 5' end and lowest for those at the 3' end of all binding sites tested. These results indicate that TRAP binds to its RNA targets by first associating with one or more repeat at the 5' end of its binding site followed by wrapping the remainder of binding site around the protein in a 5' to 3' direction. This directional binding is novel among RNA-binding proteins. We suggest that this mechanism of binding is important for TRAP-mediated transcription attenuation control of the trp operon.

Regulation of transcription attenuation and translation initiation by allosteric control of an RNA-binding protein: the Bacillus subtilis TRAP protein

Tryptophan allosterically controls the 11-subunit trp RNA-binding attenuation protein (TRAP) of Bacillus subtilis. When activated by tryptophan, TRAP binds to multiple trinucleotide repeats in target transcripts. TRAP is responsible for the decision to terminate transcription in the leader region of the trpEDCFBA operon or to allow transcription to proceed into the structural genes. TRAP also regulates translation of trpE by promoting formation of an RNA structure that prevents ribosome binding. In addition, bound TRAP regulates translation initiation of pabA, trpP and ycbK by directly blocking ribosome binding. The anti-TRAP protein inhibits TRAP activity by competing with RNA for the RNA binding surface of TRAP.

The trp RNA-binding attenuation protein of Bacillus subtilis regulates translation of the tryptophan transport gene trpP (yhaG) by blocking ribosome binding

Expression of the Bacillus subtilis tryptophan biosynthetic genes (trpEDCFBA and pabA [trpG]) is regulated in response to tryptophan by TRAP, the trp RNA-binding attenuation protein. TRAP-mediated regulation of the tryptophan biosynthetic genes includes a transcription attenuation and two distinct translation control mechanisms. TRAP also regulates translation of trpP (yhaG), a single-gene operon that encodes a putative tryptophan transporter. Its translation initiation region contains triplet repeats typical of TRAP-regulated mRNAs. We found that regulation of trpP and pabA is unaltered in a rho mutant strain. Results from filter binding and gel mobility shift assays demonstrated that TRAP binds specifically to a segment of the trpP transcript that includes the untranslated leader and translation initiation region. While the affinities of TRAP for the trpP and pabA transcripts are similar, TRAP-mediated translation control of trpP is much more extensive than for pabA. RNA footprinting revealed that the trpP TRAP binding site consists of nine triplet repeats (five GAG, three UAG, and one AAG) that surround and overlap the trpP Shine-Dalgarno (S-D) sequence and translation start codon. Results from toeprint and RNA-directed cell-free translation experiments indicated that tryptophan-activated TRAP inhibits TrpP synthesis by preventing binding of a 30S ribosomal subunit. Taken together, our results establish that TRAP regulates translation of trpP by blocking ribosome binding. Thus, TRAP coordinately regulates tryptophan synthesis and transport by three distinct mechanisms: attenuation transcription of the trpEDCFBA operon, promoting formation of the trpE S-D blocking hairpin, and blocking ribosome binding to the pabA and trpP transcripts.

Analysis of HutP-dependent transcription antitermination in the Bacillus subtilis hut operon: identification of HutP binding sites on hut antiterminator RNA and the involvement of the N-terminus of HutP in binding of HutP to the antiterminator RNA

We investigated HutP-dependent transcription antitermination of the Bacillus subtilis hut operon. In vitro transcription assays with the B. subtilissigmaA-containing RNA polymerase indicated that HutP inhibits transcription termination at the internal terminator by binding to the antiterminator on hut mRNA in the presence of histidine. Ethylnitrosourea modification interference assays and mutational analyses of the interference sites showed that interaction of HutP with a region containing three UAG trinucleotide sequences, which is located on top of the antiterminator structure, is critical for hut antitermination in vivo. Results from kinetic analysis of binding of HutP to RNA containing various portions of the antiterminator sequences indicated that secondary structure is required for binding of HutP to the region containing three UAG triplets in the antiterminator. The in vivo HutP antiterminator activity was reduced by the mutations in the N-terminal region of HutP. The HutP variants with H4A, R7A, I9A and Q26A mutations exhibited reduced binding affinities to the antiterminator RNA in vitro. A 25-mer peptide consisting of amino acid residues 2-26 of HutP bound to the antiterminator RNA. These results indicated that the N-terminus of HutP is involved in binding of HutP to the antiterminator RNA.

Characterization of a trp RNA-binding Attenuation Protein (TRAP) Mutant with Tryptophan Independent RNA Binding Activity

TRAP (trp RNA-binding attenuation protein) is an 11 subunit RNA-binding protein that regulates expression of genes involved in tryptophan metabolism (trp) in Bacillus subtilis in response to changes in intracellular tryptophan concentration. When activated by binding up to 11 tryptophan residues, TRAP binds to the mRNAs of several trp genes and down-regulates their expression. Recently, a TRAP mutant was found that binds RNA in the absence of tryptophan. In this mutant protein, Thr30, which is part of the tryptophan-binding site, is replaced with Val (T30V). We have compared the RNA-binding properties of T30V and wild-type (WT) TRAP, as well as of a series of hetero-11-mers containing mixtures of WT and T30V TRAP subunits. The most significant difference between the interaction of T30V and WT TRAP with RNA is that the affinity of T30V TRAP is more dependent on ionic strength. Analysis of the hetero-11-mers allowed us to examine how subunits interact within an 11-mer with regard to binding to tryptophan or RNA. Our data suggest that individual subunits retain properties similar to those observed when they are in homo-11-mers and that individual G/UAG triplets within the RNA can bind to TRAP differently.

Zinc is required for assembly and function of the anti-trp RNA-binding attenuation protein, AT

The anti-TRAP protein (AT) of Bacillus subtilis regulates expression of the trp operon and other genes concerned with tryptophan metabolism. AT acts by inhibiting the tryptophan-activated trp RNA-binding attenuation protein (TRAP). AT is an oligomer of identical 53-residue polypeptides; it is produced in response to the accumulation of uncharged tRNA(Trp). Each AT polypeptide has two cysteine-rich clusters that correspond to the signature motif of the cysteine-rich zinc-binding domain of the chaperone protein DnaJ. Here we characterize the putative zinc-binding domain of AT and establish the importance of zinc for AT assembly and activity. AT is shown to contain Zn(II) at a ratio of one ion per monomer. Bound zinc is necessary for maintenance of the quaternary structure of AT; the removal of zinc converts the AT complex into inactive monomers. All four cysteine residues in the AT polypeptide are involved in Zn(II) coordination. Chemical cross-linking analyses indicate that the AT functional oligomer is a hexamer composed of two trimers. Substituting alanine for any cysteine residue of AT results in rapid degradation of the mutant protein in vivo. We propose a model for the AT trimer in which three AT chains are held together by three zinc atoms, each coordinated by the N-terminal segment and the C-terminal segment of separate AT polypeptides.

Influence of induced fit in the interaction of Bacillus subtilis trp RNA-binding attenuator protein and its RNA antiterminator target oligomer

In the presence of excess tryptophan, tryptophan-activated TRAP (trp RNA-binding attenuator protein) binds to a specific target in the trp-leader transcript, which induces the formation of a transcription terminator and transcription halts in the leader region. In the absence of tryptophan, TRAP does not bind RNA, an antiterminator forms, and the operon is expressed. Although the ternary complex involving TRAP (Bacillus stearothermophilus), tryptophan, and the RNA target has recently been crystallized, efforts to obtain structural data for the apo-form of TRAP (in any species) have not been successful. We have used multidimensional/multinuclear nuclear magnetic resonance (NMR) spectroscopy to probe the structure-function relationship in the TRAP-activated system, and have obtained high-resolution multidimensional/multinuclear NMR spectra of TRAP in all three of its functional states: tryptophan-free or apo-TRAP, tryptophan-activated TRAP, and tryptophan-activated TRAP-RNA ternary complex. Chemical shift perturbation analysis of the NMR data clarifies the interpretation of results obtained from previous crystal studies. Results presented herein demonstrate that tryptophan binding induces an essential structural change in TRAP that supports high-affinity binding of the RNA target oligonucleotide.

TROSY-NMR studies of the 91kDa TRAP protein reveal allosteric control of a gene regulatory protein by ligand-altered flexibility

The tryptophan biosynthesis genes of several Bacilli are controlled through terminator/anti-terminator transcriptional attenuation. This process is regulated by tryptophan-dependent binding of the trp RNA-binding attenuation protein (TRAP) to the leader region of the trp operon mRNA, precluding formation of the antiterminator RNA hairpin, and allowing formation of the less stable terminator hairpin. Crystal structures are available of TRAP in complex with tryptophan and in ternary complex with tryptophan and RNA. However, no structure of TRAP in the absence of tryptophan is available; thus, the mechanism of allostery remains unclear. We have used transverse relaxation optimized spectroscopy (TROSY)-based NMR experiments to study the mechanism of ligand-mediated allosteric regulation in the 90.6kDa 11-mer TRAP. By recording a series of two-dimensional 15N-edited TROSY NMR spectra of TRAP from the thermophile Bacillus stearothermophilus over an extended range of temperatures, we have found tryptophan binding to be temperature-dependent, in agreement with the previously observed temperature-dependent RNA binding. Triple-resonance TROSY-based NMR spectra recorded at 55 degrees C have allowed us to obtain backbone resonance assignments for uniformly 2H,13C,15N-labeled TRAP in the inactive form and in the active form (free and bound to tryptophan). On the basis of ligand-dependent differential line-broadening and chemical shift perturbations, coupled with the results of proteolytic sensitivity measurements, we infer that tryptophan-modulated protein flexibility (dynamics) plays a central role in TRAP function by altering its RNA-binding affinity. Furthermore, because the crystal structures show that the ligand is buried completely in the bound state, we speculate that such dynamic behavior may be important to enable rapid response to changes in intracellular tryptophan levels. Thus, we propose that allosteric control of TRAP is accomplished by ligand-altered protein dynamics.

Using hetero-11-mers composed of wild type and mutant subunits to study tryptophan binding to TRAP and its role in activating RNA binding

Expression of genes involved in tryptophan metabolism in Bacillus subtilis is regulated by the TRAP protein in response to changes in l-tryptophan levels. TRAP binding to several RNA targets that contain between 9 and 11 (G/U)AG repeats regulates transcription and/or translation of these genes. TRAP consists of 11 identical subunits and is activated to bind RNA by binding up to 11 molecules of tryptophan. To investigate the mechanism by which tryptophan binding activates TRAP, we generated hetero-11-mers containing different proportions of subunits from wild type (WT) TRAP that bind tryptophan and from a mutant TRAP (Thr(25) to Ala) defective in tryptophan binding. Studies of these hetero-11-mers show that tryptophan-binding sites created from active subunits bind tryptophan with similar affinity to those in WT homo-11-mers, whereas sites containing the T25A substitution do not bind tryptophan. Hetero-11-mers with very few (one or two) bound tryptophans show only 10-fold lower affinity than WT TRAP for an RNA with 11 GAG repeats, whereas TRAP with no bound tryptophan shows no detectable binding to this RNA. We also demonstrate that tryptophan binding induces a conformational change in TRAP in the vicinity of the RNA-binding site, suggesting a possible mechanism for activation of RNA binding.

Transcription attenuation

In this review, we describe a variety of mechanisms that bacteria use to regulate transcription elongation in order to control gene expression in response to changes in their environment. Together, these mechanisms are known as attenuation and antitermination, and both involve controlling the formation of a transcription terminator structure in the RNA transcript prior to a structural gene or operon. We examine attenuation and antitermination from the point of view of the different biomolecules that are used to influence the RNA structure. Attenuation of many amino acid biosynthetic operons, particularly in enteric bacteria, is controlled by ribosomes translating leader peptides. RNA-binding proteins regulate attenuation, particularly in gram-positive bacteria such as Bacillus subtilis. Transfer RNA is also used to bind to leader RNAs and influence transcription antitermination in a large number of amino acyl tRNA synthetase genes and several biosynthetic genes in gram-positive bacteria. Finally, antisense RNA is involved in mediating transcription attenuation to control copy number of several plasmids.

Creating hetero-11-mers composed of wild-type and mutant subunits to study RNA binding to TRAP

TRAP (trp RNA-binding attenuation protein) is an RNA-binding protein that regulates expression of the tryptophan biosynthetic genes in Bacillus subtilis by binding to RNA targets that contain multiple GAG and UAG repeats. TRAP is composed of 11 identical subunits arranged symmetrically in a ring. The secondary structure of the protein consists entirely of antiparallel beta-sheets, beta-turns, and loops. We show here that the TRAP 11-mer can be reversibly denatured into unfolded monomers by guanidine hydrochloride. Removing the denaturant allows the protein to spontaneously renature into fully functional 11-mers. Based on this finding, we developed a subunit mixing method to hybridize wild-type and mutant subunits into heteromeric 11-mers by denaturation followed by subunit mixing renaturation. This method allows the study of subunit cooperativity in protein-ligand interaction such as RNA binding. Our data further support and extend the previously proposed two-step model for RNA binding to TRAP by showing that the initiation of binding requires at least one fully active subunit in the protein combined with one fully functional repeat in the RNA. The initiation complex tethers the RNA on the protein, thus allowing cooperative interaction with the remainder of the repeats.

The anti-trp RNA-binding attenuation protein (Anti-TRAP), AT, recognizes the tryptophan-activated RNA binding domain of the TRAP regulatory protein

In Bacillus subtilis, the trp RNA-binding attenuation protein (TRAP) regulates expression of genes involved in tryptophan metabolism in response to the accumulation of l-tryptophan. Tryptophan-activated TRAP negatively regulates expression by binding to specific mRNA sequences and either promoting transcription termination or blocking translation initiation. Conversely, the accumulation of uncharged tRNA(Trp) induces synthesis of an anti-TRAP protein (AT), which forms a complex with TRAP and inhibits its activity. In this report, we investigate the structural features of TRAP required for AT recognition. A collection of TRAP mutant proteins was examined that were known to be partially or completely defective in tryptophan binding and/or RNA binding. Analyses of AT interactions with these proteins were performed using in vitro transcription termination assays and cross-linking experiments. We observed that TRAP mutant proteins that had lost the ability to bind RNA were no longer recognized by AT. Our findings suggest that AT acts by competing with messenger RNA for the RNA binding domain of TRAP. B. subtilis AT was also shown to interact with TRAP proteins from Bacillus halodurans and Bacillus stearothermophilus, implying that the structural elements required for AT recognition are conserved in the TRAP proteins of these species. Analyses of AT interaction with B. stearothermophilus TRAP at 60 degrees C demonstrated that AT is active at this elevated temperature.

Systematic analysis of a conserved region of the aminoglycoside 6'-N-acetyltransferase type Ib

Alanine-scanning mutagenesis was applied to the aminoglycoside 6'-N-acetyltransferase type Ib conserved motif B, and the effects of the substitutions were analyzed by measuring the MICs of kanamycin (KAN) and its semisynthetic derivative, amikacin (AMK). Several substitutions resulted in no major change in MICs. E167A and F171A resulted in derivatives that lost the ability to confer resistance to KAN and AMK. P155A, P157A, N159A, L160A, I163A, K168A, and G170A conferred intermediate levels of resistance. Y166A resulted in an enzyme derivative with a modified specificity; it conferred a high level of resistance to KAN but lost the ability to confer resistance to AMK. Although not as pronounced, the resistance profiles conferred by substitutions N159A and G170A were related to that conferred by Y166A. These phenotypes, taken together with previous results indicating that mutant F171L could not catalyze acetylation of AMK when the assays were carried out at 42 degrees C (D. Panaite and M. Tolmasky, Plasmid 39:123-133, 1998), suggest that some motif B amino acids play a direct or indirect role in acceptor substrate specificity. MICs of AMK and KAN for cells harboring the substitution C165A were high, suggesting that the active form of the enzyme may not be a dimer formed through a disulfide bond. Furthermore, this result indicated that the acetylation reaction occurs through a direct mechanism rather than a ping-pong mechanism that includes a transient transfer of the acetyl group to a cysteine residue. Deletion of fragments at the C terminus demonstrated that up to 10 amino acids could be deleted without a loss of activity.

Expression of the Bacillus subtilis trpEDCFBA operon is influenced by translational coupling and Rho termination factor

The trp RNA-binding attenuation protein (TRAP) regulates expression of the Bacillus subtilis trpEDCFBA operon by transcription attenuation and translational control mechanisms. Both mechanisms require binding of tryptophan-activated TRAP to 11 (G/U)AG repeats in the trp leader transcript. trpE translational control involves formation of a TRAP-dependent RNA structure that sequesters the trpE Shine-Dalgarno (SD) sequence (the SD blocking hairpin). By comparing expression levels from trpE'-'lacZ translational fusions controlled by the wild-type leader or by a leader that cannot form the SD blocking hairpin, we found that translational control requires a tryptophan concentration higher than that required for transcription attenuation. We also found that inhibition of trpE translation by the SD blocking hairpin does not alter the stability of the downstream message. Since the coding sequences for trpE and trpD overlap by 29 nucleotides, we examined expression levels from trpED'-'lacZ translational fusions to determine if these two genes are translationally coupled. We found that introduction of a UAA stop codon in trpE resulted in a substantial reduction in expression. Since expression was partially restored in the presence of a tRNA suppressor, our results indicate that trpE and trpD are translationally coupled. We determined that the coupling mechanism is TRAP independent and that formation of the SD blocking hairpin regulates trpD translation via translational coupling. We also constructed a rho mutation to investigate the role of Rho-dependent termination in trp operon expression. We found that TRAP-dependent formation of the SD blocking hairpin allows Rho access to the nascent transcript, causing transcriptional polarity.

Using nucleotide analogs to probe protein-RNA interactions

Synthetic nucleotide analogs provide the opportunity to evaluate the importance of individual functional groups on the RNA in protein-RNA complexes. The general approach is to incorporate analogs at a defined position(s) in the RNA target and to evaluate the effect of this substitution on the thermodynamic stability of the protein-RNA complex. The underlying assumption is that if the presence of the analog reduces the stability of the complex, then the functional groups that are altered in the analog interact with the protein. Here we describe the protocols for incorporation of nucleotide analogs either by in vitro transcription using T7 RNA polymerase or by synthetic chemistry. We also describe how we have used this approach to study the interaction of the TRAP protein from Bacillus subtilis with its cognate RNAs consisting of 11 repeats of GAG and/or UAG triplets. By comparing the results of these analog studies with the crystal structure of TRAP bound to an RNA containing 11 GAG repeats, we are able to see that all the functional groups identified by analogs forge direct interactions with the protein. Analog studies also correctly identified residues that do not contact the protein. Moreover, analogs can have indirect effects on the complex stability by altering the structural properties of the RNA.

Structural symmetry and protein function

The majority of soluble and membrane-bound proteins in modern cells are symmetrical oligomeric complexes with two or more subunits. The evolutionary selection of symmetrical oligomeric complexes is driven by functional, genetic, and physicochemical needs. Large proteins are selected for specific morphological functions, such as formation of rings, containers, and filaments, and for cooperative functions, such as allosteric regulation and multivalent binding. Large proteins are also more stable against denaturation and have a reduced surface area exposed to solvent when compared with many individual, smaller proteins. Large proteins are constructed as oligomers for reasons of error control in synthesis, coding efficiency, and regulation of assembly. Symmetrical oligomers are favored because of stability and finite control of assembly. Several functions limit symmetry, such as interaction with DNA or membranes, and directional motion. Symmetry is broken or modified in many forms: quasisymmetry, in which identical subunits adopt similar but different conformations; pleomorphism, in which identical subunits form different complexes; pseudosymmetry, in which different molecules form approximately symmetrical complexes; and symmetry mismatch, in which oligomers of different symmetries interact along their respective symmetry axes. Asymmetry is also observed at several levels. Nearly all complexes show local asymmetry at the level of side chain conformation. Several complexes have reciprocating mechanisms in which the complex is asymmetric, but, over time, all subunits cycle through the same set of conformations. Global asymmetry is only rarely observed. Evolution of oligomeric complexes may favor the formation of dimers over complexes with higher cyclic symmetry, through a mechanism of prepositioned pairs of interacting residues. However, examples have been found for all of the crystallographic point groups, demonstrating that functional need can drive the evolution of any symmetry.

trp RNA-binding attenuation protein-5' stem-loop RNA interaction is required for proper transcription attenuation control of the Bacillus subtilis trpEDCFBA operon

The trp RNA-binding attenuation protein (TRAP) regulates expression of the Bacillus subtilis trpEDCFBA operon by a novel transcription attenuation mechanism. Tryptophan-activated TRAP binds to the nascent trp leader transcript by interacting with 11 (G/U)AG repeats, 6 of which are present in an antiterminator structure. TRAP binding to these repeats prevents formation of the antiterminator, thereby promoting formation of an overlapping intrinsic terminator. A third stem-loop structure that forms at the extreme 5' end of the trp leader transcript also plays a role in the transcription attenuation mechanism. The 5' stem-loop increases the affinity of TRAP for trp leader RNA. Results from RNA structure mapping experiments demonstrate that the 5' stem-loop consists of a 3-bp lower stem, a 5-by-2 asymmetric internal loop, a 6-bp upper stem, and a hexaloop at the apex of the structure. Footprinting results indicate that TRAP interacts with the 5' stem-loop and that this interaction differs depending on the number of downstream (G/U)AG repeats present in the transcript. Expression studies with trpE'-'lacZ translational fusions demonstrate that TRAP-5' stem-loop interaction is required for proper regulation of the trp operon. 3' RNA boundary experiments indicate that the 5' structure reduces the number of (G/U)AG repeats required for stable TRAP-trp leader RNA association. Thus, TRAP-5' stem-loop interaction may increase the likelihood that TRAP will bind to the (G/U)AG repeats in time to block antiterminator formation.

cis-acting regulatory sequences for antitermination in the transcript of the Bacillus subtilis hut operon and histidine-dependent binding of HutP to the transcript containing the regulatory sequences

The location of the cis-acting regulatory region for histidine-dependent antitermination of the Bacillus subtilis hut operon was determined. A secondary structure, whose sequences partially overlap with the downstream terminator, was found in the regulatory region of the hut transcript. Mutational analysis of the regulatory region showed that the secondary structure was required for histidine-dependent antitermination. An electrophoretic mobility-shift assay demonstrated that, in response to the presence of histidine and Mg2+, purified HutP bound hut RNA bearing putative secondary structure but not RNA lacking the potential to form putative secondary structure. Native gel electrophoresis showed that HutP existed as a hexamer. A filter-binding assay revealed that the concentration of histidine required for half-maximal binding of HutP to RNA was 3.1 mM and that the Kd for binding of HutP to RNA was approximately 0.56 microM in the presence of histidine. These results suggested that putative secondary structure in the regulatory region of hut mRNA could function as an antiterminator to inhibit the formation of the terminator structure and that HutP causes expression of the hut structural genes by binding to the putative antiterminator structure in response to the presence of histidine.