Paul Gollnick

Posttranscription Initiation Control of Tryptophan Metabolism in Bacillus subtilis by the trp RNA-Binding Attenuation Protein (TRAP), anti-TRAP, and RNA Structure

Organisms utilize a wide range of regulatory mechanisms to control gene expression. While regulation of transcription initiation is a common regulatory strategy, it is now apparent that this is only the starting point. Bacteria have developed several sophisticated regulatory mechanisms that allow

TROSY-NMR studies of the 91 kDa 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.

Kinetic and Thermodynamic Analysis of the Interaction between TRAP (trp RNA-binding Attenuation Protein) of Bacillus subtilis and trp Leader RNA

In Bacillus subtilis, expression of the tryptophan biosynthetic genes is regulated in response to tryptophan by an RNA-binding protein called TRAP (trp RNA-binding attenuation protein). TRAP has been shown to contain 11 identical subunits arranged in a symmetrical ring. Kinetic and thermodynamic parameters of the interaction between tryptophan-activated TRAP and trp leader RNA were studied. Results from glycerol gradients and mobility shift gels indicate that two TRAP 11-mers bind to each trp leader RNA. A filter binding assay was used to determine an apparent binding constant of 8.0 ± 1.3 × 10M (K = 0.12 ± 0.02 nM) for TRAP and an RNA containing residues +36 to +92 of the trp leader RNA in 1 mML-tryptophan at 37°C. The temperature dependence of K was somewhat unexpected demonstrating that the ΔH of the interaction is highly unfavorable at +15.9 kcal mol. Therefore, the interaction is completely driven by a ΔS of +97 cal mol K. The interaction between tryptophan-activated TRAP and trp leader RNA displayed broad salt and pH activity profiles. Finally, the rate of RNA dissociation from the RNA•TRAP•tryptophan ternary complex was found to be very slow in high concentrations of tryptophan (>40 μM) but increased in lower tryptophan concentrations. This suggests that dissociation of tryptophan from the ternary complex is the rate-limiting step in RNA dissociation.

APOBEC3A cytidine deaminase induces RNA editing in monocytes and macrophages

The extent, regulation and enzymatic basis of RNA editing by cytidine deamination are incompletely understood. Here we show that transcripts of hundreds of genes undergo site-specific C>U RNA editing in macrophages during M1 polarization and in monocytes in response to hypoxia and interferons. This editing alters the amino acid sequences for scores of proteins, including many that are involved in pathogenesis of viral diseases. APOBEC3A, which is known to deaminate cytidines of single-stranded DNA and to inhibit viruses and retrotransposons, mediates this RNA editing. Amino acid residues of APOBEC3A that are known to be required for its DNA deamination and anti-retrotransposition activities were also found to affect its RNA deamination activity. Our study demonstrates the cellular RNA editing activity of a member of the APOBEC3 family of innate restriction factors and expands the understanding of C>U RNA editing in mammals.

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, thetrp 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 tRNATrp 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 fromBacillus 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 °C demonstrated that AT is active at this elevated temperature.

THE TRP RNA-BINDING ATTENUATION PROTEIN (TRAP) FROM BACILLUS SUBTILIS BINDS TO UNSTACKED TRP LEADER RNA

TRAP ( t rp 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 °C and 47 °C and then decreasing from 47 °C to 67 °C. Differential scanning calorimetry and circular dichroism spectroscopy demonstrate that TRAP is highly thermostable with few detectable changes in the structure between 25 °C and 70 °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 thattrp 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.

Recombinant human lactoferrin expressed in glycoengineered Pichia pastoris: effect of terminal N-acetylneuraminic acid on in vitro secondary humoral immune response

Traditional production of therapeutic glycoproteins relies on mammalian cell culture technology. Glycoproteins produced by mammalian cells invariably display N-glycan heterogeneity resulting in a mixture of glycoforms the composition of which varies from production batch to production batch. However, extent and type of N-glycosylation has a profound impact on the therapeutic properties of many commercially relevant therapeutic proteins making control of N-glycosylation an emerging field of high importance. We have employed a combinatorial library approach to generate glycoengineered Pichia pastoris strains capable of displaying defined human-like N-linked glycans at high uniformity. The availability of these strains allows us to elucidate the relationship between specific N-linked glycans and the function of glycoproteins. The aim of this study was to utilize this novel technology platform and produce two human-like N-linked glycoforms of recombinant human lactoferrin (rhLF), sialylated and non-sialylated, and to evaluate the effects of terminal N-glycan structures on in vitro secondary humoral immune responses. Lactoferrin is considered an important first line defense protein involved in protection against various microbial infections. Here, it is established that glycoengineered P. pastoris strains are bioprocess compatible. Analytical protein and glycan data are presented to demonstrate the capability of glycoengineered P. pastoris to produce fully humanized, active and immunologically compatible rhLF. In addition, the biological activity of the rhLF glycoforms produced was tested in vitro revealing the importance of N-acetylneuraminic (sialic) acid as a terminal sugar in propagation of proper immune responses.

Cellular Levels of trp RNA-Binding Attenuation Protein in Bacillus subtilis

Expression of the Bacillus subtilis trp genes is negatively regulated by an 11-subunit trp RNA-binding attenuation protein (TRAP), which is activated to bind RNA by binding l-tryptophan. We used Western blotting to estimate that there are 200 to 400 TRAP 11-mer molecules per cell in cells grown in either minimal or rich medium.

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 (Thr25 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.

Regulation of the Tryptophan Biosynthetic Genes in Bacillus halodurans: Common Elements but Different Strategies than Those Used by Bacillus subtilis

In Bacillus subtilis, an RNA binding protein called TRAP regulates both transcription and translation of the tryptophan biosynthetic genes. Bacillus halodurans is an alkaliphilic Bacillus species that grows at high pHs. Previous studies of this bacterium have focused on mechanisms of adaptation for growth in alkaline environments. We have characterized the regulation of the tryptophan biosynthetic genes in B. halodurans and compared it to that in B. subtilis. B. halodurans encodes a TRAP protein with 71% sequence identity to the B. subtilis protein. Expression of anthranilate synthetase, the first enzyme in the pathway to tryptophan, is regulated significantly less in B. halodurans than in B. subtilis. Examination of the control of the B. halodurans trpEDCFBA operon both in vivo and in vitro shows that only transcription is regulated, whereas in B. subtilis both transcription of the operon and translation of trpE are controlled. The attenuation mechanism that controls transcription in B. halodurans is similar to that in B. subtilis, but there are some differences in the predicted RNA secondary structures in the B. halodurans trp leader region, including the presence of a potential anti-antiterminator structure. Translation of trpG, which is within the folate operon in both bacilli, is regulated similarly in the two species.