Real-Time Fluorescence-Based Approaches to Disentangle Mechanisms of a Protein's RNA Chaperone Activity.

RNA-binding proteins with an RNA chaperone activity exert either one or both of the following catalytic activities: (1) RNA annealing, i.e., the protein supports intra- as well as intermolecular RNA-RNA interactions and (2) strand displacement, i.e., the protein mediates the exchange of individual strands of a preexisting RNA duplex. To discriminate and further characterize these activities, it requires defined assay systems. These are based on entirely or partially complementary RNA oligonucleotides that are labeled with fluorescent and/or quencher dyes. The non-catalyzed and the protein-supported associations of the RNA molecules are followed by a real-time fluorescence resonance energy transfer (FRET) system. By site-specific modification of the RNAs or the protein, the substrate- and protein-specific parameters of the RNA chaperone activity can be explored and identified.In this chapter, we present strategies on the design of labeled RNA molecules to be used to characterize the activities of an RNA-binding protein and explain how to monitor progress curves of RNA annealing and strand displacement reactions in single cuvette or well-plate scales. We provide sets of equations and models to determine and analyze different types of reactions, e.g., by calculation of first- and second-order rate constants. Likewise, we demonstrate how to exploit these simple experimental setups to elucidate elementary principles of the reaction mechanisms performed by the protein of interest by applying basic kinetic applications, such as ARRHENIUS and linear free energy relationship analyses. These approaches will be explained by providing example plots and graphs from experiments investigating the RNA chaperone activities of the RNA-binding proteins NF90-NF45 and AUF1 p45.

The iron-sulfur-containing HypC-HypD scaffold complex of the [NiFe]-hydrogenase maturation machinery is an ATPase.

HypD and HypC, or its paralogue HybG in Escherichia coli, form the core of the scaffold complex that synthesizes the Fe(CN)2 CO component of the bimetallic NiFe-cofactor of [NiFe]-hydrogenase. We show here that purified HypC-HypD and HybG-HypD complexes catalyse hydrolysis of ATP to ADP (kcat  â‰… 0.85·s-1 ); the ATPase activity of the individual proteins was between 5- and 10-fold lower than that of the complex. Pre-incubation of HypD with ATP was necessary to restore full activity upon addition of HybG. The conserved Cys41 residue on HypD was essential for full ATPase activity of the complex. Together, our data suggest that HypD undergoes ATP-dependent conformational activation to facilitate complex assembly in preparation for substrate reduction.

The RGG/RG motif of AUF1 isoform p45 is a key modulator of the protein's RNA chaperone and RNA annealing activities.

The RNA-binding protein AUF1 regulates post-transcriptional gene expression by affecting the steady state and translation levels of numerous target RNAs. Remodeling of RNA structures by the largest isoform AUF1 p45 was recently demonstrated in the context of replicating RNA viruses, and involves two RNA remodeling activities, i.e. an RNA chaperone and an RNA annealing activity. AUF1 contains two non-identical RNA recognition motifs (RRM) and one RGG/RG motif located in the C-terminus. In order to determine the functional significance of each motif to AUF1's RNA-binding and remodeling activities we performed a comprehensive mutagenesis study and characterized the wildtype AUF1, and several variants thereof. We demonstrate that each motif contributes to efficient RNA binding and remodeling by AUF1 indicating a tight cooperation of the RRMs and the RGG/RG motif. Interestingly, the data identify two distinct roles for the arginine residues of the RGG/RG motif for each RNA remodeling activity. First, arginine-mediated stacking interactions promote AUF1's helix-destabilizing RNA chaperone activity. Second, the electropositive character of the arginine residues is the major driving force for the RNA annealing activity. Thus, we provide the first evidence that arginine residues of an RGG/RG motif contribute to the mechanism of RNA annealing and RNA chaperoning.

Molecular Details of Retinal Guanylyl Cyclase 1/GCAP-2 Interaction.

The rod outer segment guanylyl cyclase 1 (ROS-GC1) is an essential component of photo-transduction in the retina. In the light-induced signal cascade, membrane-bound ROS-GC1 restores cGMP levels in the dark in a calcium-dependent manner. With decreasing calcium concentration in the intracellular compartment, ROS-GC1 is activated via the intracellular site by guanylyl cyclase-activating proteins (GCAP-1/-2). Presently, the exact activation mechanism is elusive. To obtain structural insights into the ROS-GC1 regulation by GCAP-2, chemical cross-linking/mass spectrometry studies using GCAP-2 and three ROS-GC1 peptides were performed in the presence and absence of calcium. The majority of cross-links were identified with the C-terminal lobe of GCAP-2 and a peptide comprising parts of ROS-GC1's catalytic domain and C-terminal extension. Consistently with the cross-linking results, surface plasmon resonance and fluorescence measurements confirmed specific binding of this ROS-GC peptide to GCAP-2 with a dissociation constant in the low micromolar range. These results imply that a region of the catalytic domain of ROS-GC1 can participate in the interaction with GCAP-2. Additional binding surfaces upstream of the catalytic domain, in particular the juxtamembrane domain, can currently not be excluded.

The Host Factor AUF1 p45 Supports Flavivirus Propagation by Triggering the RNA Switch Required for Viral Genome Cyclization.

In previous studies, we showed that the cellular RNA-binding protein AUF1 supports the replication process of the flavivirus West Nile virus. Here we demonstrate that the protein also enables effective proliferation of dengue virus and Zika virus, indicating that AUF1 is a general flavivirus host factor. Further studies demonstrated that the AUF1 isoform p45 significantly stimulates the initiation of viral RNA replication and that the protein's RNA chaperone activity enhances the interactions of the viral 5'UAR and 3'UAR genome cyclization sequences. Most interestingly, we observed that AUF1 p45 destabilizes not only the 3'-terminal stem-loop (3'SL) but also 5'-terminal stem-loop B (SLB) of the viral genome. RNA structure analyses revealed that AUF1 p45 increases the accessibility of defined nucleotides within the 3'SL and SLB and, in this way, exposes both UAR cyclization elements. Conversely, AUF1 p45 does not modulate the fold of stem-loop A (SLA) at the immediate genomic 5' end, which is proposed to function as a promoter of the viral RNA-dependent RNA polymerase (RdRp). These findings suggest that AUF1 p45, by destabilizing specific stem-loop structures within the 5' and 3' ends of the flaviviral genome, assists genome cyclization and concurrently enables the RdRp to initiate RNA synthesis. Our study thus highlights the role of a cellular RNA-binding protein inducing a flaviviral RNA switch that is crucial for viral replication.IMPORTANCE The genus Flavivirus within the Flaviviridae family includes important human pathogens, such as dengue, West Nile, and Zika viruses. The initiation of replication of the flaviviral RNA genome requires a transformation from a linear to a cyclized form. This involves considerable structural reorganization of several RNA motifs at the genomic 5' and 3' ends. Specifically, it needs a melting of stem structures to expose complementary 5' and 3' cyclization elements to enable their annealing during cyclization. Here we show that a cellular RNA chaperone, AUF1 p45, which supports the replication of all three aforementioned flaviviruses, specifically rearranges stem structures at both ends of the viral genome and in this way permits 5'-3' interactions of cyclization elements. Thus, AUF1 p45 triggers the RNA switch in the flaviviral genome that is crucial for viral replication. These findings represent an important example of how cellular (host) factors promote the propagation of RNA viruses.

Arginine methylation enhances the RNA chaperone activity of the West Nile virus host factor AUF1 p45.

A prerequisite for the intracellular replication process of the Flavivirus West Nile virus (WNV) is the cyclization of the viral RNA genome, which enables the viral replicase to initiate RNA synthesis. Our earlier studies indicated that the p45 isoform of the cellular AU-rich element binding protein 1 (AUF1) has an RNA chaperone activity, which supports RNA cyclization and viral RNA synthesis by destabilizing a stem structure at the WNV RNA's 3'-end. Here we show that in mammalian cells, AUF1 p45 is consistently modified by arginine methylation of its C terminus. By a combination of different experimental approaches, we can demonstrate that the methyltransferase PRMT1 is necessary and sufficient for AUF1 p45 methylation and that PRMT1 is required for efficient WNV replication. Interestingly, in comparison to the nonmethylated AUF1 p45, the methylated AUF1 p45(aDMA) exhibits a significantly increased affinity to the WNV RNA termini. Further data also revealed that the RNA chaperone activity of AUF1 p45(aDMA) is improved and the methylated protein stimulates viral RNA synthesis considerably more efficiently than the nonmethylated AUF1 p45. In addition to its destabilizing RNA chaperone activity, we identified an RNA annealing activity of AUF1 p45, which is not affected by methylation. Arginine methylation of AUF1 p45 thus represents a specific determinant of its RNA chaperone activity while functioning as a WNV host factor. Our data suggest that the methylation modifies the conformation of AUF1 p45 and in this way affects its RNA binding and restructuring activities.

AUF1 p45 promotes West Nile virus replication by an RNA chaperone activity that supports cyclization of the viral genome.

UNLABELLED: A central aspect of current virology is to define the function of cellular proteins (host factors) that support the viral multiplication process. This study aimed at characterizing cellular proteins that assist the RNA replication process of the prevalent human pathogen West Nile virus (WNV). Using in vitro and cell-based approaches, we defined the p45 isoform of AU-rich element RNA-binding protein 1 (AUF1) as a host factor that enables efficient WNV replication. It was demonstrated that AUF1 p45 has an RNA chaperone activity, which aids the structural rearrangement and cyclization of the WNV RNA that is required by the viral replicase to initiate RNA replication. The obtained data suggest the RNA chaperone activity of AUF1 p45 is an important determinant of the WNV life cycle. IMPORTANCE: In this study, we identified a cellular protein, AUF1 (also known as heterogeneous ribonucleoprotein D [hnRNPD]), acting as a helper (host factor) of the multiplication process of the important human pathogen West Nile virus. Several different variants of AUF1 exist in the cell, and one variant, AUF1 p45, was shown to support viral replication most significantly. Interestingly, we obtained a set of experimental data indicating that a main function of AUF1 p45 is to modify and thus prepare the West Nile virus genome in such a way that the viral enzyme that generates progeny genomes is empowered to do this considerably more efficiently than in the absence of the host factor. The capability of AUF1 p45 to rearrange the West Nile virus genome was thus identified to be an important aspect of a West Nile virus infection.

In vivo phosphorylation and in vitro autophosphorylation-inactivation of Kluyveromyces lactis hexokinase KlHxk1.

The bifunctional hexokinase KlHxk1 is a key component of glucose-dependent signal transduction in Kluyveromyces lactis. KlHxk1 is phosphorylated in vivo and undergoes ATP-dependent autophosphorylation-inactivation in vitro. This study identifies serine-15 as the site of in vivo phosphorylation and serine-157 as the autophosphorylation-inactivation site. X-ray crystallography of the in vivo phosphorylated enzyme indicates the existence of a ring-shaped symmetrical homodimer carrying two phosphoserine-15 residues. In contrast, small-angle X-ray scattering and equilibrium sedimentation analyses reveal the existence of monomeric phosphoserine-15 KlHxk1 in solution. While phosphorylation at serine-15 and concomitant homodimer dissociation are likely to be involved in glucose signalling, mechanism and putative physiological significance of KlHxk1 inactivation by autophosphorylation at serine-157 remain to be established.

The DEAD-box helicase DDX3 supports the assembly of functional 80S ribosomes.

The DEAD-box helicase DDX3 has suggested functions in innate immunity, mRNA translocation and translation, and it participates in the propagation of assorted viruses. Exploring initially the role of DDX3 in the life cycle of hepatitis C virus, we observed the protein to be involved in translation directed by different viral internal ribosomal entry sites. Extension of these studies revealed a general supportive role of DDX3 in translation initiation. DDX3 was found to interact in an RNA-independent manner with defined components of the translational pre-initiation complex and to specifically associate with newly assembling 80S ribosomes. DDX3 knock down and in vitro reconstitution experiments revealed a significant function of the protein in the formation of 80S translation initiation complexes. Our study implies that DDX3 assists the 60S subunit joining process to assemble functional 80S ribosomes.

Sequence and expression of the chicken membrane-associated phospholipases A1 alpha (LIPH) and beta (LIPI).

Cancer/testis antigens (CTA) are a heterogeneous group of antigens that are expressed preferentially in tumor cells and testis. Based on this definition the human membrane-associated phospholipase A1 beta (lipase family member I, LIPI) has been identified as CTA. The high homology of LIPI and the membrane-associated phospholipase A1 alpha (lipase family member H, LIPH) suggests that both genes are derived from a common ancestor by gene duplication. In contrast to human LIPI, human LIPH is expressed in several tissues. LIPI sequences have only been identified in mammals. Here, we describe the identification of LIPI in non-mammalian vertebrates. Based on the conserved genomic organization of LIPI and LIPH we identified sequences for both lipases in birds and fishes. In all vertebrates the LIPI locus is neighbored by a member of the RNA binding motif (RBM) family, RBM11. By sequencing of reverse transcriptase-polymerase chain reaction products we determined the sequences of LIPI and LIPH messenger RNA from broilers. We found that the sequence homology between LIPI and LIPH is much higher in non-mammalian species than in mammals. In addition, we found broad expression of LIPI in broilers, resembling the expression profile of LIPH. Our data suggest that LIPI is a CTA only in mammalian species and that the unique sequence features of the mammalian LIPI/RBM11 locus have evolved together with the CTA-like expression pattern of LIPI.

Fast amide proton exchange reveals close relation between native-state dynamics and unfolding kinetics.

It has long been recognized that many proteins fold and unfold via partially structured intermediates, but it is still unclear why some proteins unfold in a two-state fashion while others do not. Here we compare the unfolding pathway of the small one-domain protein barstar with its dynamics under native conditions. Using very fast proton-exchange experiments, extensive dynamic heterogeneity within the native-state ensemble could be identified. Especially the dynamics of helix 3, covering the hydrophobic core of the molecule, is found to be clearly cooperative but decoupled from the global dynamics. Moreover, an initial unfolding of this helix followed by the breakdown of the remaining tertiary structure can be concluded from the comparison of the proton exchange experiments with unfolding kinetics detected by stopped-flow fluorescence. We infer that the unfolding pathway of barstar is closely coupled to its native-state dynamics.

Coulomb forces control the density of the collapsed unfolded state of barstar.

Although it has been recently shown that unfolded polypeptide chains undergo a collapse on transfer from denaturing to native conditions, the forces determining the dynamics and the size of the collapsed form have not yet been understood. Here, we use single-molecule fluorescence resonance energy transfer experiments on the small protein barstar to characterize the unfolded chain in guanidinium chloride (GdmCl) and urea. The unfolded protein collapses on decreasing the concentration of denaturants. Below the critical concentration of 3.5 M denaturant, the collapse in GdmCl leads to a more dense state than in urea. Since it is known that GdmCl suppresses electrostatic interactions, we infer that Coulomb forces are the dominant forces acting in the unfolded barstar under native conditions. This hypothesis is clearly buttressed by the finding of a compaction of the unfolded barstar by addition of KCl at low urea concentrations.