The interaction of RNA with TRAP: the role of triplet repeats and separating spacer nucleotides.

The trp RNA-binding attenuation protein (TRAP) regulates expression of the tryptophan biosynthetic genes in several Bacilli by binding to the leader region of the nascent trp mRNA, inhibiting continued transcription. The 11 subunit TRAP molecule is active in complex with tryptophan, and binds consequently an RNA target segment consisting of 11 (G/U)AG triplets, each separated by two or three non-conserved "spacer" nucleotides. Here, we report the first crystal structures of TRAP in a complex with RNA containing UAG triplets separated by two nucleotides and in a complex with RNA containing GAG triplets separated by three nucleotides. Comparison with known structures of TRAP-RNA complexes shows that both substitution of G-1 with U-1 in the triplet and addition of an extra spacer nucleotide lead to a more flexible complex. This suggests an explanation why, in the trp leader RNA, all three-nucleotide spacer regions are followed by a G-1 nucleotide. Taken together, the structures demonstrate that RNA binding to TRAP is mediated by specific interactions involving the A-2 and G-3 nucleotides of the triplet. This is accompanied by the disruption of stacking interactions between the bases of the other nucleotides, contributing to the increase in entropy that drives binding.

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.

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.

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.