Trp RNA-binding Attenuation Protein Research Articles

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.

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.

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.

Specificity of TRAP-RNA interactions: crystal structures of two complexes with different RNA sequences.

The trp RNA-binding attenuation protein (TRAP) regulates expression of the tryptophan biosynthetic genes in bacilli by binding to the leader region of the nascent trp operon mRNA. When activated by binding tryptophan, the 11-subunit circular TRAP molecule binds to a target sequence consisting of 11 (G/U)AG repeats, separated by two or three variable 'spacer' nucleotides. Reported here are two crystal structures of TRAP bound to RNAs containing 11 GAG repeats separated by UU and CC spacer nucleotides, determined at 1.75 and 2.50 A resolution, respectively. These show the spacer regions of the RNA molecules to be highly flexible, making no direct hydrogen-bonding contacts with the protein. Comparison of these structures with the previous structure of TRAP bound to (GAGAU)(10)GAG RNA, in which the spacer nucleotides stack with each other close to the protein surface, shows that the RNA can adopt different conformations depending on the sequence of the spacer regions. This gives insight into the structural basis of the specificity of TRAP and into the mechanism of binding.

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.

The mechanism of RNA binding to TRAP: initiation and cooperative interactions.

The trp RNA-binding Attenuation Protein (TRAP) from Bacillus subtilis is an 11-subunit protein that binds a series of 11 GAG and UAG repeats separated by two to three-spacer nucleosides in trp leader mRNA. The structure of TRAP bound to an RNA containing 11 GAG repeats shows that the RNA wraps around the outside of the protein ring with each GAG interacting with the protein in nearly identical fashion. The only direct hydrogen bond interactions between the protein and the RNA backbone are to the 2'-hydroxyl groups on the third G of each repeat. Replacing all 11 of these guanosines with deoxyriboguanosine eliminates measurable binding to TRAP. In contrast, a single riboguanosine in an otherwise entirely DNA oligonucleotide dramatically stabilizes TRAP binding, and facilitates the interaction of the remaining all-DNA portion with the protein. Studies of TRAP binding to RNAs with between 2 and 11 GAGs, UAGs, AAGs, or CAGs showed that the stability of a TRAP-RNA complex is not directly proportional to the number of repeats in the RNA. These studies also showed that the effect of the identity of the residue in the first position of the triplet, with regard to binding to TRAP, is dependent on the number of repeats in the RNA. Together these data support a model in which TRAP binds to RNA by first forming an initial complex with a small subset of the repeats followed by a cooperative interaction with the remaining triplets.

A Bacillus subtilis operon containing genes of unknown function senses tRNATrp charging and regulates expression of the genes of tryptophan biosynthesis.

Strains of Bacillus subtilis containing a temperature-sensitive tryptophanyl-tRNA synthetase produce elevated levels of the tryptophan pathway enzymes, when grown at high temperatures in the presence of excess tryptophan. This increase is because of reduced availability of the tryptophan-activated trp RNA-binding attenuation protein (TRAP). To test the hypothesis that this elevated trp gene expression was caused by the overproduction of a transcript capable of binding and sequestering TRAP, a computer program was designed to search the B. subtilis genome sequence for additional potential TRAP binding sites. A region containing a stretch of (G/A)AG trinucleotide repeats, characteristic of a TRAP binding site, was identified in the yczA-ycbK operon. We show that transcriptional regulation of the yczA-ycbK operon is controlled by the T-box antitermination mechanism in response to the level of uncharged tRNA(Trp), and that the presence of a trpS1 mutant allele increases production of the yczA-ycbK transcript. Elevated yczA-ycbK expression was shown to activate transcription of the trp operon. Deletion of the yczA-ycbK operon abolishes the trpS1 effect on trp gene expression. The purpose of increasing expression of the genes of tryptophan biosynthesis in the trpS mutant would be to provide additional tryptophan to overcome the charged tRNA(Trp) deficiency. Therefore, in B. subtilis, as in Escherichia coli, transcription of the tryptophan biosynthetic genes is regulated in response to changes in the extent of charging of tRNA(Trp) as well as the availability of tryptophan.

Effects of Mutations in the l-Tryptophan Binding Pocket of the trp RNA-binding Attenuation Protein ofBacillus subtilis

The Bacillus subtilis tryptophan biosynthetic genes are regulated by the trp RNA-binding attenuation protein (TRAP). Cooperative binding of L-tryptophan activates TRAP so that it can bind to RNA. The crystal structure revealed that L-tryptophan forms nine hydrogen bonds with various amino acid residues of TRAP. We performed site-directed mutagenesis to determine the importance of several of these hydrogen bonds in TRAP activation. We tested both alanine substitutions as well as substitutions more closely related to the natural amino acid at appropriate positions. Tryptophan binding mutations were identified in vivo having unchanged, reduced, or completely eliminated repression activity. Several of the in vivo defective TRAP mutants exhibited reduced affinity for tryptophan in vitro but did not interfere with RNA binding at saturating tryptophan concentrations. However, a 10-fold decrease in TRAP affinity for tryptophan led to an almost complete loss of regulation, whereas increased TRAP affinity for tryptophan had little or no effect on the in vivo regulatory activity of TRAP. One hydrogen bond was found to be dispensable for TRAP activity, whereas two others appear to be essential for TRAP function. Another mutant protein exhibited tryptophan-independent RNA binding activity. We also found that trp leader RNA increases the affinity of TRAP for tryptophan.

RNA-binding proteins: TRAPping RNA bases.

In Bacillus subtilis, tryptophan biosynthesis is regulated by a mechanism called attenuation. The new crystal structure of the 'trp RNA binding attenuation protein', TRAP, in complex with RNA has provided new structural insights into how proteins can bind RNA to regulate transcription and translation.

Probing the TRAP-RNA interaction with nucleoside analogs.

The trp RNA-binding Attenuation Protein (TRAP) from Bacillus subtilis binds a series of GAG and UAG repeats separated by 2-3 nonconserved spacer nucleotides in trp leader mRNA. To identify chemical groups on the RNA required for stability of the TRAP-RNA complex, we introduced several different nucleoside analogs into each pentamer of the RNA sequence 5'-(UAGCC)-3' repeated 11 times and measured their effect on the TRAP-RNA interaction. Deoxyribonucleoside substitutions revealed that a 2'-hydroxyl group (2'-OH) is required only on the guanosine occupying the third residue of the RNA triplets for high-affinity binding to TRAP. The remaining hydroxyl groups are dispensable. Base analog substitutions identified all of the exocyclic functional groups and N1 nitrogens of adenine and guanine in the second and third nucleotides, respectively, of the triplets as being involved in binding TRAP. In contrast, none of the substitutions made in the first residue caused any detectable changes in affinity, indicating that elements of these bases are not necessary for complex formation and stability. Studies using abasic nucleotides in the first residue of the triplets and in the two spacer residues confirmed that the majority of the specificity and stability of the TRAP-RNA complex is provided by the AG dinucleotide of the triplet repeats. In addition to direct effects on binding, we demonstrate that the N7-nitrogen of adenosine and guanosine in UAG triplet and the 2'-OHs of (UAGCC)11 RNA are involved in the formation of an as yet undetermined structure that interferes with TRAP binding.

Structure of the trp RNA-binding attenuation protein, TRAP, bound to RNA.

The trp RNA-binding attenuation protein (TRAP) regulates expression of the tryptophan biosynthetic genes of several bacilli by binding single-stranded RNA. The binding sequence is composed of eleven triplet repeats, predominantly GAG, separated by two or three non-conserved nucleotides. Here we present the crystal structure of a complex of TRAP and a 53-base single-stranded RNA containing eleven GAG triplets, revealing that each triplet is accommodated in a binding pocket formed by beta-strands. In the complex, the RNA has an extended structure without any base-pairing and binds to the protein mostly by specific protein-base interactions. Eleven binding pockets on the circular TRAP 11-mer form a belt with a diameter of about 80 A. This simple but elegant mechanism of arresting the RNA segment by encircling it around a protein disk is applicable to both transcription, when TRAP binds the nascent RNA, and to translation, when TRAP binds the same sequence within a non-coding leader region of the messenger RNA.

Regulatory Features of the trp Operon and the Crystal Structure of the trp RNA-binding Attenuation Protein from Bacillus stearothermophilus

Characterization of both the cis and trans -acting regulatory elements indicates that the Bacillus stearothermophilustrp operon is regulated by an attenuation mechanism similar to that which controls the trp operon in Bacillus subtilis. Secondary structure predictions indicate that the leader region of thetrp mRNA is capable of folding into terminator and anti- terminator RNA structures. B.stearothermophilus also encodes an RNA-binding protein with 77% sequence identity with the RNA-binding protein (TRAP) that regulates attenuation in B.subtilis. The X-ray structure of this protein has been determined in complex with l -tryptophan at 2.5Å resolution. Like the B.subtilis protein, B.stearothermophilus TRAP has 11 subunits arranged in a ring-like structure. The central cavities in these two structures have different sizes and opposite charge distributions, and packing within the B.stearothermophilus TRAP crystal form does not generate the head-to-head dimers seen in the B.subtilis protein, suggesting that neither of these properties is functionally important. However, the mode of l -tryptophan binding and the proposed RNA binding surfaces are similar, indicating that both proteins are activated by l -tryptophan and bind RNA in essentially the same way. As expected, the TRAP:RNA complex from B.stearothermophilus is significantly more thermostable than that from B.subtilis, with optimal binding occurring at 70°C.

RNA Structure Inhibits the TRAP (trpRNA-binding AttenuationProtein)-RNA Interaction

TRAP (trp RNA-binding attenuation protein) regulates expression of the tryptophan biosynthetic genes in response to tryptophan in Bacillus subtilis by binding to two sites containing a series of 9 or 11 (G/U)AG triplet repeats that are generally separated by two or three spacer nucleotides. Previous mutagenesis experiments have identified three TRAP residues, Lys-37, Lys-56, and Arg-58 that are essential for RNA binding. The location of these residues on the TRAP oligomer supports the proposal that RNA binds TRAP by encircling the TRAP oligomer. In this work, we show that RNAs containing 11 GAG or UAG repeats separated by CC dinucleotide spacers (((G/U)AGCC)11) form stable structures that inhibit binding to TRAP. This conclusion is based on the effects of temperature and Mg2+ on the affinity of TRAP for RNAs with CC spacers combined with UV hyperchromicity and circular dichroism. Furthermore, introducing the base analogue 7-deazaguanosine in the ((G/U)AGCC)11 RNAs stabilized the TRAP-RNA interaction. This effect was associated with decreased stability of the RNA structure as measured by circular dichroism spectroscopy. The precise nature of the structure of the ((G/U)AGCC)11 RNAs is not known but evidence is presented that it involves noncanonical interactions. We also observed that substitution of Arg-58 with Lys further reduced the ability of TRAP to interact with structured RNAs. Since in vivo function of TRAP may involve binding to structured RNAs, we suggest a potential function for this residue, which is conserved in TRAP from three different bacilli.

Trp RNA-binding Attenuation Protein-mediated Long Distance RNA Refolding Regulates Translation of trpE inBacillus subtilis

Expression of the trpEDCFBA operon is regulated at both the transcriptional and translational levels by the trp RNA-binding attenuation protein (TRAP) of Bacillus subtilis. When cells contain sufficient levels of tryptophan to activate TRAP, the protein binds to trp operon transcripts as they are being synthesized, most often causing transcription termination. However, termination is never 100% efficient, and transcripts that escape termination are subject to translational control. We determined that TRAP-mediated translational control of trpE can occur via a novel RNA conformational switch mechanism. When TRAP binds to the 5'-untranslated leader segment of a trp operon read-through transcript, it can disrupt a large secondary structure containing a portion of the TRAP binding target. This promotes refolding of the RNA such that the trpE Shine-Dalgarno sequence, located more than 100 nucleotides downstream from the TRAP binding site, becomes sequestered in a stable RNA hairpin. Results from cell-free translation, ribosome toeprint, and RNA structure mapping experiments demonstrate that formation of this structure reduces TrpE synthesis by blocking ribosome access to the trpE ribosome binding site. The role of the Shine-Dalgarno blocking hairpin in controlling translation of trpE was confirmed by examining the effect of multiple nucleotide substitutions that abolish the structure without altering the Shine-Dalgarno sequence itself. The possibility of protein-mediated RNA refolding as a general mechanism in controlling gene expression is discussed.

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

In Bacillus subtilis, expression of the trp genes is negatively regulated by an RNA binding protein called TRAP ( t rp R NA-binding A ttenuation P rotein), which is activated to bind RNA by binding l-tryptophan. TRAP contains 11 identical subunits assembled in a symmetric ring. We have used alanine-scanning mutagenesis to analyze the functions of surface amino acid residues of TRAP. The in vivo regulatory activity of each mutant TRAP was analyzed in a B. subtilis reporter strain containing a trpE′-′lacZ fusion. Mutant TRAP proteins with defective in vivo regulatory activities were characterized in vitro by measuring their tryptophan binding and RNA binding activities. Most of the mutant proteins with altered tryptophan binding, either affinity or cooperativity, contained substituted residues located on two loops formed by residues 25 to 33 and residues 49 to 52, as well as on the β-strand and β-turn contiguous with these loops. Substitution of three residues (Lys37, Lys56 and Arg58) with alanine resulted in significant decreases in the RNA binding activity of TRAP without altering tryptophan binding. Structural analysis shows that these three residues are directly aligned on the outer edge of TRAP. Further mutagenic analysis of these three residues revealed that only lysine or arginine residues at positions 37 or 58 allow proper TRAP function, whereas at position 56, only lysine is functional. Residue Asn20 is the only other residue in TRAP that is located on the line formed by residues 37, 56 and 58, and virtually any amino acid residue is functional at position 20. We propose that RNA wraps around TRAP by interacting with residues Lys37, Lys56 and Arg58.

The trpRNA-binding Attenuation Protein (TRAP) from Bacillus subtilis Binds to Unstackedtrp Leader RNA

TRAP (trp RNA-binding attenuation protein) is a tryptophan-activated RNA-binding protein that regulates expression of the trp biosynthetic genes by binding to a series of GAG and UAG trinucleotide repeats generally separated by two or three spacer nucleotides. Previously, we showed that TRAP contains 11 identical subunits arranged in a symmetrical ring. Based on this structure, we proposed a model for the TRAP.RNA interaction where the RNA wraps around the protein with each repeat of the RNA contacting one or a combination of two adjacent subunits of the TRAP oligomer. Here, we have shown that RNAs selected in vitro based on their ability to bind tryptophan-activated TRAP contain multiple G/UAG repeats and show a strong bias for pyrimidines as the spacer nucleotides between these repeats. The affinity of the TRAP.RNA interaction displays a nonlinear temperature dependence, increasing between 5 degrees C and 47 degrees C and then decreasing from 47 degrees C to 67 degrees C. Differential scanning calorimetry and circular dichroism spectroscopy demonstrate that TRAP is highly thermostable with few detectable changes in the structure between 25 degrees C and 70 degrees C, suggesting that the temperature dependence of this interaction reflects changes in the RNA. Results from circular dichroism and UV absorbance spectroscopy support this hypothesis, demonstrating that trp leader RNA becomes unstacked upon binding TRAP. We propose that the bias toward pyrimidines in the spacer nucleotides of the in vitro selected RNAs represents the inability of Us and Cs to form stable base stacking interactions, which allows the flexibility needed for the RNA to wrap around the TRAP oligomer.

The trp RNA-binding attenuation protein regulates TrpG synthesis by binding to the trpG ribosome binding site of Bacillus subtilis.

The trpG gene of Bacillus subtilis encodes a glutamine amidotransferase subunit which is involved in the biosynthesis of L-tryptophan and folic acid. The trp RNA-binding attenuation protein (TRAP) is involved in controlling expression of trpG at the level of translation in response to changes in the intracellular concentration of tryptophan. We performed in vitro experiments using purified TRAP to elucidate the mechanism of TRAP-dependent trpG regulation. A TRAP-trpG RNA footprint analysis showed that tryptophan-activated TRAP interacts with one UAG, one AAG, and seven GAG repeats present in the trpG transcript. Results from ribosome and TRAP toeprint experiments indicated that the ribosome and TRAP binding sites overlap. Experiments with a B. subtilis cell-free translation system demonstrated that TRAP inhibits TrpG synthesis. Thus, TRAP regulates translation of trpG by blocking ribosome access to the trpG ribosome binding site. Our results are consistent with a model in which each tryptophan-activated TRAP subunit interacts with one trinucleotide repeat in an RNA target, thereby wrapping the transcript around the periphery of the TRAP complex.

The trp RNA-binding attenuation protein (TRAP) regulates the steady-state levels of transcripts of the Bacillus subtilis folate operon.

The Bacillus subtilis folate operon contains nine genes. The first six genes are involved in the biosynthesis of folic acid and tryptophan and have been characterized previously. The 3'-region of the folate operon contains three additional ORFs: orf3, potentially encoding a DNA-binding protein of 68 amino acids, orf4, encoding a protein of 338 amino acids with homology to the Orf1 of the E. coli fis operon, and a putative lysyl-tRNA synthetase gene (LysS). Four transcripts were identified which encode the first two, eight or all nine proteins or only the last protein LysS. The folate operon contains two promoters, one upstream of the first gene and the second preceding LysS. Transcription of the entire folate operon starts 33 bp upstream of the ATG codon of pab, the first gene of the operon. The mtrB-encoded trp RNA-binding attenuation protein (TRAP) dramatically reduces the steady-state levels of the folate operon transcripts encoding the first eight and all nine proteins, but only has a relatively small effect on the steady-state level of the 2.1 kb transcript encoding the first two genes of the operon, pab and trpG. In addition, transcription of the folate operon is regulated in a growth-phase-dependent manner. Transcripts were present in very low levels after mid-exponential phase, but were dramatically increased directly after transfer of the cells to fresh medium. These results indicate that transcription of the folate operon is regulated by TRAP and also depends on the growth phase of the culture.

A temperature-sensitive trpS mutation interferes with trp RNA-binding attenuation protein (TRAP) regulation of trp gene expression in Bacillus subtilis.

In Bacillus subtilis, the tryptophan-activated trp RNA-binding attenuation protein (TRAP) regulates expression of the seven tryptophan biosynthetic genes by binding to specific repeat sequences in the transcripts of the trp operon and of the folate operon, the operon containing trpG. Steinberg observed that strains containing a temperature-sensitive mutant form of tryptophanyl-tRNA synthetase, encoded by the trpS1 allele, produced elevated levels of the tryptophan pathway enzymes, when grown at high temperatures in the presence of excess L-tryptophan (W. Steinberg, J. Bacteriol. 117:1023-1034, 1974). We have confirmed this observation and have shown that expression of two reporter gene fusions, trpE'-'lacZ and trpG'-'lacZ, is also increased under these conditions. Deletion of the terminator or antiterminator RNA secondary structure involved in TRAP regulation of trp operon expression eliminated the trpS1 effect, suggesting that temperature-sensitive expression was mediated by the TRAP protein. Analysis of expression of mtrB, the gene encoding the TRAP subunit, both by examination of a lacZ translational fusion and by measuring the intracellular levels of TRAP by immunoblotting, indicated that the trpS1-induced increase in trp gene expression was not due to inhibition of mtrB expression or to alteration of the amount of TRAP present per cell. Increasing the cellular level of TRAP by overexpressing mtrB partially counteracted the trpS1 effect, demonstrating that active TRAP was limiting in the trpS1 mutant. We also showed that elevated trp operon expression was not due to increased transcription initiation at the upstream aroF promoter, a promoter that also contributes to trp operon expression. We postulate that the increase in trp gene expression observed in the trpS1 mutant is due to the reduced availability of functional TRAP. This could result from inhibition of TRAP function by uncharged tRNA(Trp) molecules or by increased synthesis of some other transcript capable of binding and sequestering the TRAP regulatory protein.

Interaction of the trp RNA-Binding attenuation protein (TRAP) of Bacillus subtilis with RNA: effects of the number of GAG repeats, the nucleotides separating adjacent repeats, and RNA secondary structure.

The 11-subunit trp RNA-binding attenuation protein of Bacillus subtilis, TRAP, regulates transcription and translation by binding to several (G/U)AG repeats present in the trp leader and trpG transcripts. Filter binding assays were used to study interactions between L-tryptophan-activated TRAP and synthetic RNAs. RNAs that contained GAG and/or UAG repeats were tested while the length and sequence of the nucleotides separating adjacent trinucleotide repeats were altered. TRAP-RNA complexes formed with transcripts containing GAG repeats were more stable than those with transcripts containing UAG repeats or alternating GAG and UAG repeats. The stability of TRAP-RNA complexes also increased substantially when the number of GAG repeats was increased from five to six and from six to seven. A gradual increase in complex stability was observed when the number of GAG repeats was increased from 7 to 11. The optimal spacer between adjacent trinucleotide repeats was found to be 2 nucleotides, with A and U residues preferred over G and C residues. TRAP binding was specific for single-stranded RNA; TRAP could not bind to RNA containing GAG repeats base paired in a stable RNA duplex. Overall, our findings suggest that each L-tryptophan-activated TRAP subunit can bind one (G/U)AG repeat and that multiple TRAP subunit-RNA binding site interactions are required for stable TRAP-RNA association.