Allosteric regulation of human poly(A)-specific ribonuclease by cap and potassium ions

Poly(A)-specific ribonuclease (PARN), a multi-domain dimeric enzyme, is a deadenylase in higher vertebrates and plants with the unique property of cap-dependent catalysis and processivity. We found that PARN is an allosteric enzyme, and potassium ions and the cap analogue were effectors with binding sites located at the RRM domain. The binding of K⁺ to the entire RRM domain led to an increase of substrate-binding affinity but a decrease in the cooperativity of the substrate-binding site, while the binding of the cap analogue decreased both the catalytic efficiency and the substrate-binding affinity. The dissimilar kinetic properties of the enzymes with and without the entire RRM domain suggested that the RRM domain played a central role in the allosteric communications of PARN regulation. The allostery is proposed to be important to the multi-level regulation of PARN to achieve precise control of the mRNA poly(A) tail length.     

Interaction between a poly(A)-specific ribonuclease and the 5' cap influences mRNA deadenylation rates in vitro

We have used an in vitro system that reproduces in vivo aspects of mRNA turnover to elucidate mechanisms of deadenylation. DAN, the major enzyme responsible for poly(A) tail shortening in vitro, specifically interacts with the 5' cap structure of RNA substrates, and this interaction is greatly stimulated by a poly(A) tail. Several observations suggest that cap-DAN interactions are functionally important for the networking between regulated mRNA stability and translation. First, uncapped RNA substrates are inefficiently deadenylated. Second, a stem-loop structure in the 5' UTR dramatically reduces deadenylation by interfering with cap-DAN interactions. Third, the addition of cap binding protein eIF4E inhibits deadenylation in vitro. These data provide insights into the early steps of substrate recognition that target an mRNA for degradation.     

Expression and purification of recombinant poly(A)-specific ribonuclease (PARN)

PARN is a poly(A)-specific ribonuclease that degrades the poly(A) tail of mRNA. We have established conditions for expressing soluble recombinant human PARN. We investigated different Escherichia coli strains, expression vectors, media and growth conditions. We found that PARN expressed from pET33 in BL21(DE3) grown in TB and induced at OD595 approximately 1 with 1 mM IPTG yielded mg amounts of soluble PARN per litre culture. Further, a purification protocol was established to purify PARN. We use His-tag affinity chromatography, HiTrap Q HP ion exchange chromatography and 7-Me-GTP-Sepharose affinity chromatography. This purification procedure render a 90-95% pure PARN. Purified recombinant PARN has enzymatic activity and will be used for further mechanistic and structural studies.     

Molecular recognition of single-stranded RNA: Neomycin binding to poly(A)

Poly(A) is a relevant sequence in cell biology due to its importance in mRNA stability and translation initiation. Neomycin is an aminoglycoside antibiotic that is well known for its ability to target various nucleic acid structures. Here it is reported that neomycin is capable of binding tightly to a single-stranded oligonucleotide (A₃₀) with a K_d in the micromolar range. CD melting experiments support complex formation and indicate a melting temperature of 47 °C. The poly(A) duplex, which melts at 44 °C (pH 5.5), was observed to melt at 61 °C in the presence of neomycin, suggesting a strong stabilization of the duplex by the neomycin.     

Inhibition of Klenow DNA polymerase and poly(A)-specific ribonuclease by aminoglycosides

Aminoglycosides are known to bind and perturb the function of catalytic RNA. Here we show that they also are potent inhibitors of protein-based catalysis using Escherichia coli Klenow polymerase (pol) and mammalian poly(A)-specific ribonuclease (PARN) as model enzymes. The inhibition was pH dependent and released in a competitive manner by Mg2+. Kinetic analysis showed that neomycin B behaved as a mixed noncompetitive inhibitor. Iron-mediated hydroxyl radical cleavage was used to show that neomycin B interfered with metal-ion binding in the active sites of both enzymes. Our analysis suggests a mechanism of inhibition where the aminoglycoside binds in the active site of the enzyme and thereby displaces catalytically important divalent metal ions. The potential causes of aminoglycoside toxicity and the usage of aminoglycosides to probe, characterize, and perturb metalloenzymes are discussed.     

Contributions of the C-terminal domain to poly(A)-specific ribonuclease (PARN) stability and self-association

Poly(A)-specific ribonuclease (PARN) catalyzes the degradation of mRNA poly(A) tail to regulate translation efficiency and mRNA decay in higher eukaryotic cells. The full-length PARN is a multi-domain protein containing the catalytic nuclease domain, the R3H domain, the RRM domain and the C-terminal intrinsically unstructured domain (CTD). The roles of the three well-structured RNA-binding domains have been extensively studied, while little is known about CTD. In this research, the impact of CTD on PARN stability and aggregatory potency was studied by comparing the thermal inactivation and denaturation behaviors of full-length PARN with two N-terminal fragments lacking CTD. Our results showed that K⁺ induced additional regular secondary structures and enhanced PARN stability against heat-induced inactivation, unfolding and aggregation. CTD prevented PARN from thermal inactivation but promoted thermal aggregation to initiate at a temperature much lower than that required for inactivation and unfolding. Blue-shift of Trp fluorescence during thermal transitions suggested that heat treatment induced rearrangements of domain organizations. CTD amplified the stabilizing effect of K⁺, implying the roles of CTD was mainly achieved by electrostatic interactions. These results suggested that CTD might dynamically interact with the main body of the molecule and release of CTD promoted self-association via electrostatic interactions.     

Coordination of divalent metal ions in the active site of poly(A)-specific ribonuclease

Poly(A)-specific ribonuclease (PARN) is a highly poly(A)-specific 3'-exoribonuclease that efficiently degrades mRNA poly(A) tails. PARN belongs to the DEDD family of nucleases, and four conserved residues are essential for PARN activity, i.e. Asp-28, Glu-30, Asp-292, and Asp-382. Here we have investigated how catalytically important divalent metal ions are coordinated in the active site of PARN. Each of the conserved amino acid residues was substituted with cysteines, and it was found that all four mutants were inactive in the presence of Mg2+. However, in the presence of Mn2+, Zn2+, Co2+, or Cd2+, PARN activity was rescued from the PARN(D28C), PARN(D292C), and PARN(D382C) variants, suggesting that these three amino acids interact with catalytically essential metal ions. It was found that the shortest sufficient substrate for PARN activity was adenosine trinucleotide (A3) in the presence of Mg2+ or Cd2+. Interestingly, adenosine dinucleotide (A) was efficiently hydrolyzed in the presence of Mn2+, Zn2+, or Co2+, suggesting that the substrate length requirement for PARN can be modulated by the identity of the divalent metal ion. Finally, introduction of phosphorothioate modifications into the A substrate demonstrated that the scissile bond non-bridging phosphate oxygen in the pro-R position plays an important role during cleavage, most likely by coordinating a catalytically important divalent metal ion. Based on our data we discuss binding and coordination of divalent metal ions in the active site of PARN.     

A nonradioactive assay for poly(a)-specific ribonuclease activity by methylene blue colorimetry

A simple nonradioactive assay, which was based on the specific shift of the absorbance maximum of methylene blue induced by its intercalation into poly(A) molecules, was developed for poly(A)-specific ribonuclease (PARN). A good linear relationship was found between the absorbance at 662 nm and the poly(A) concentration. The assay conditions, including the concentration of methylene blue, the incubation temperature and time, and the poly(A) concentration were evaluated and optimized.     

Self-association of poly(A)-specific ribonuclease (PARN) triggered by the R3H domain

Poly(A)-specific ribonuclease (PARN) is a deadenylase with three RNA-binding domains (the nuclease, R3H and RRM domains) and a C-terminal domain. PARN participates in diverse physiological processes by regulating mRNA fates through deadenylation. PARN mainly exists as a dimer in dilute solutions. In this research, we found that PARN could self-associate into tetramer and high-order oligomers both in vitro and in living cells. Mutational and spectroscopic analysis indicated that PARN oligomerization was triggered by the R3H domain, which led to the solvent-exposed Trp219 fluorophore to become buried in a solvent-inaccessible microenvironment. The RRM and C-terminal domains also played a role in modulating the dissociation rate of the tetrameric PARN. Enzymatic analysis indicated that tetramerization did not affect the catalytic behavior of the full-length PARN and truncated enzymes containing the RRM domain, which might be caused by the high propensity of the dimeric proteins to self-associate into oligomers. Tetramerization significantly enhanced the catalytic activity and processivity of the truncated form with the removal of the RRM and C-terminal domains. The results herein suggested that self-association might be one of the regulation methods for PARN to achieve a highly regulated deadenylase activity. We propose that self-association may facilitate PARN to concentrate around the target mRNAs by restricted diffusion.     

Inhibition of human poly(A)-specific ribonuclease (PARN) by purine nucleotides: kinetic analysis

Poly(A)-specific ribonuclease (PARN) is a cap-interacting and poly(A)-specific 3'-exoribonuclease that efficiently degrades mRNA poly(A) tails. Based on the enzyme's preference for its natural substrates, we examined the role of purine nucleotides as potent effectors of human PARN activity. We found that all purine nucleotides tested can reduce poly(A) degradation by PARN. Detailed kinetic analysis revealed that RTP nucleotides behave as non-competitive inhibitors while RDP and RMP exhibit competitive inhibition. Mg(2 + ) which is a catalytically important mediator of PARN activity can release inhibition of RTP and RDP but not RMP. Although many strategies have been proposed for the regulation of PARN activity, very little is known about the modulation of PARN activity by small molecule effectors, such as nucleotides. Our data imply that PARN activity can be modulated by purine nucleotides in vitro, providing an additional simple regulatory mechanism.     

Inhibition of human poly(A)-specific ribonuclease (PARN) by purine nucleotides: kinetic analysis

Poly(A)-specific ribonuclease (PARN) is a cap-interacting and poly(A)-specific 3′-exoribonuclease that efficiently degrades mRNA poly(A) tails. Based on the enzyme's preference for its natural substrates, we examined the role of purine nucleotides as potent effectors of human PARN activity. We found that all purine nucleotides tested can reduce poly(A) degradation by PARN. Detailed kinetic analysis revealed that RTP nucleotides behave as non-competitive inhibitors while RDP and RMP exhibit competitive inhibition. Mg^{2 +} which is a catalytically important mediator of PARN activity can release inhibition of RTP and RDP but not RMP. Although many strategies have been proposed for the regulation of PARN activity, very little is known about the modulation of PARN activity by small molecule effectors, such as nucleotides. Our data imply that PARN activity can be modulated by purine nucleotides in vitro, providing an additional simple regulatory mechanism.     

Effect of magnesium ions on the thermal stability of human poly(A)-specific ribonuclease

Poly(A)-specific ribonuclease (PARN), a member of the DEDD family, is a key enzyme involved in the deadenylation of mRNA in higher eukaryotic cells. In this research, it was found that Mg(2+) could protect PARN against thermal inactivation by increasing the midpoint of inactivation and decreasing the inactivation rate. This protective effect was unique to Mg(2+) in a concentration-dependent manner. However, the thermal unfolding and aggregation was promoted by the addition of Mg(2+) at high temperatures. These results revealed that Mg(2+) might have dual effects on PARN stability: protecting the active site but endangering the overall structural stability.     

Role of the RRM domain in the activity, structure and stability of poly(A)-specific ribonuclease

Poly(A) specific ribonuclease (PARN), which contains a catalytic domain and two RNA-binding domains (R3H and RRM), acts as a key enzyme in eukaryotic organisms to regulate the stability of mRNA by degrading the 3' poly-(A) tail. In this research, the activity, structure and stability were compared between the full-length 74kDa PARN, the proteolytic 54kDa fragment with half of the RRM, and a truncated 46kDa form completely missing the RRM. The results indicated that the 46kDa one had the lowest activity and substrate binding affinity, the most hydrophobic exposure in the native state and the least stability upon denaturation. The dissimilarity in the activity, structure and stability of the three PARNs revealed that the entire RRM domain not only contributed to the substrate binding and efficient catalysis of PARN, but also stabilized the overall structures of the protein. Spectroscopic experiments suggested that the RRM domain might be structurally adjacent to the R3H domain, and thus provide a basis for the cooperative binding of poly(A) by the two RNA-binding domains as well as the catalytic domain.     

Upstream of N-Ras C-terminal cold shock domains mediate poly(A) specificity in a novel RNA recognition mode and bind poly(A) binding protein

RNA binding proteins (RBPs) often engage multiple RNA binding domains (RBDs) to increase target specificity and affinity. However, the complexity of target recognition of multiple RBDs remains largely unexplored. Here we use Upstream of N-Ras (Unr), a multidomain RBP, to demonstrate how multiple RBDs orchestrate target specificity. A crystal structure of the three C-terminal RNA binding cold-shock domains (CSD) of Unr bound to a poly(A) sequence exemplifies how recognition goes beyond the classical ππ-stacking in CSDs. Further structural studies reveal several interaction surfaces between the N-terminal and C-terminal part of Unr with the poly(A)-binding protein (pAbp). All interactions are validated by mutational analyses and the high-resolution structures presented here will guide further studies to understand how both proteins act together in cellular processes.     

Global architecture of human poly(A)-specific ribonuclease by atomic force microscopy in liquid and dynamic light scattering

Deadenylation is the initial and often rate-limiting step in the main pathways of eukaryotic mRNA decay. Poly(A)-specific ribonuclease (PARN) is a eukaryotic enzyme that efficiently degrades mRNA poly(A) tails. Structural and functional studies have shown that human PARN is composed of at least three functional domains, i.e. the catalytic nuclease domain and two RNA binding domains, the R3H and the RNA recognition motif (RRM), respectively. However, the complete structure of the full length protein is still unknown. We have investigated the global architecture of human PARN by atomic force microscopy (AFM) imaging in buffered milieu and report for the first time the dimensions of the full length protein at subnanometer resolution. The AFM images of single PARN molecules reveal compact ellipsoidal dimers (10.9 × 7.6 × 4.6nm). The dimeric form of PARN was confirmed by dynamic light scattering (DLS) measurements that rendered a molecular weight of 161 kDa, in accordance with previous crystal structures of PARN fragments showing a dimeric composition. We discuss a putative internal arrangement of three functional domains within the full length PARN dimer.     

Distinct roles of the R3H and RRM domains in poly(A)-specific ribonuclease structural integrity and catalysis

Deadenylases specifically catalyze the degradation of eukaryotic mRNA poly(A) tail in the 3′- to 5′-end direction with the release of 5′-AMP as the product. Among the deadenylase family, poly(A)-specific ribonuclease (PARN) is unique in its domain composition, which contains three potential RNA-binding domains: the catalytic nuclease domain, the R3H domain and the RRM domain. In this research, we investigated the roles of these RNA-binding domains by comparing the structural features and enzymatic properties of mutants lacking either one or two of the three RNA-binding domains. The results showed that the R3H domain had the ability to bind various oligonucleotides at the micromolar level with no oligo(A) specificity. The removal of the R3H domain dissociated PARN into monomers, which still possessed the RNA-binding ability and catalytic functions. Unlike the critical role of the RRM domain in PARN processivity, the removal of the R3H domain did not affect the catalytic pattern of PARN. Our results suggested that both R3H and RRM domains were essential for the high affinity of long poly(A) substrate, but the R3H domain did not contribute to the substrate recognition of PARN. Compared to the RRM domain, the R3H domain played a more important role in the structural integrity of the dimeric PARN. The multiple RNA-binding domain architecture endows PARN the property of highly efficient catalysis in a highly processive mode.     

Crystal structure and RNA binding properties of the RNA recognition motif (RRM) and AlkB domains in human AlkB homolog 8 (ABH8), an enzyme catalyzing tRNA hypermodification

Humans express nine paralogs of the bacterial DNA repair enzyme AlkB, an iron/2-oxoglutarate-dependent dioxygenase that reverses alkylation damage to nucleobases. The biochemical and physiological roles of these paralogs remain largely uncharacterized, hampering insight into the evolutionary expansion of the AlkB family. However, AlkB homolog 8 (ABH8), which contains RNA recognition motif (RRM) and methyltransferase domains flanking its AlkB domain, recently was demonstrated to hypermodify the anticodon loops in some tRNAs. To deepen understanding of this activity, we performed physiological and biophysical studies of ABH8. Using GFP fusions, we demonstrate that expression of the Caenorhabditis elegans ABH8 ortholog is widespread in larvae but restricted to a small number of neurons in adults, suggesting that its function becomes more specialized during development. In vitro RNA binding studies on several human ABH8 constructs indicate that binding affinity is enhanced by a basic α-helix at the N terminus of the RRM domain. The 3.0-Å-resolution crystal structure of a construct comprising the RRM and AlkB domains shows disordered loops flanking the active site in the AlkB domain and a unique structural Zn(II)-binding site at its C terminus. Although the catalytic iron center is exposed to solvent, the 2-oxoglutarate co-substrate likely adopts an inactive conformation in the absence of tRNA substrate, which probably inhibits uncoupled free radical generation. A conformational change in the active site coupled to a disorder-to-order transition in the flanking protein segments likely controls ABH8 catalytic activity and tRNA binding specificity. These results provide insight into the functional and structural adaptations underlying evolutionary diversification of AlkB domains.