Structural distinctions between NAD+ riboswitch domains 1 and 2 determine differential folding and ligand binding

Riboswitches are important gene regulatory elements frequently encountered in bacterial mRNAs. The recently discovered nadA riboswitch contains two similar, tandemly arrayed aptamer domains, with the first domain possessing high affinity for nicotinamide adenine dinucleotide (NAD⁺). The second domain which comprises the ribosomal binding site in a putative regulatory helix, however, has withdrawn from detection of ligand-induced structural modulation thus far, and therefore, the identity of the cognate ligand and the regulation mechanism have remained unclear. Here, we report crystal structures of both riboswitch domains, each bound to NAD⁺. Furthermore, we demonstrate that ligand binding to domain 2 requires significantly higher concentrations of NAD⁺ (or ADP retaining analogs) compared to domain 1. Using a fluorescence spectroscopic approach, we further shed light on the structural features which are responsible for the different ligand affinities, and describe the Mg²⁺-dependent, distinct folding and pre-organization of their binding pockets. Finally, we speculate about possible scenarios for nadA RNA gene regulation as a putative two-concentration sensor module for a time-controlled signal that is primed and stalled by the gene regulation machinery at low ligand concentrations (domain 1), and finally triggers repression of translation as soon as high ligand concentrations are reached in the cell (domain 2).     

Molecular mechanism for preQ1-II riboswitch function revealed by molecular dynamics

Riboswitches are RNA molecules that regulate gene expression using conformational change, affected by binding of small molecule ligands. A crystal structure of a ligand-bound class II preQ₁ riboswitch has been determined in a previous structural study. To gain insight into the dynamics of this riboswitch in solution, eight total molecular dynamic simulations, four with and four without ligand, were performed using the Amber force field. In the presence of ligand, all four of the simulations demonstrated rearranged base pairs at the 3′ end, consistent with expected base-pairing from comparative sequence analysis in a prior bioinformatic analysis; this suggests the pairing in this region was altered by crystallization. Additionally, in the absence of ligand, three of the simulations demonstrated similar changes in base-pairing at the ligand binding site. Significantly, although most of the riboswitch architecture remained intact in the respective trajectories, the P3 stem was destabilized in the ligand-free simulations in a way that exposed the Shine–Dalgarno sequence. This work illustrates how destabilization of two major groove base triples can influence a nearby H-type pseudoknot and provides a mechanism for control of gene expression by a fold that is frequently found in bacterial riboswitches.     

Roles of Mg2+ in TPP-dependent riboswitch

We quantified the effect of Mg(2+) on thiamine pyrophosphate (TPP) binding to TPP-dependent thiA riboswitch RNA. The association constant of TPP binding to the riboswitch at 20 degrees C increased from 1.2 x 10(6) to 50 x 10(6) M(-1) as the Mg(2+) concentration increased from 0 to 1 mM. Furthermore, circular dichroic spectra under various conditions showed that 1 mM Mg(2+) induced a local structural change of the riboswitch, which might be pivotal for TPP binding. These results indicate that a physiological concentration of Mg(2+) can regulate TPP binding to the thiA riboswitch.     

Adriamycin-catalyzed aerobic photooxidation of NAD dimers to NAD+

The photooxidation of the dimers of nicotinamide adenine dinucleotide, (NAD)2, is catalyzed by adriamycin under aerobic conditions. (NAD)2 and O2 react in 1:1 molar ratio to yield 2 mol of NAD+. Experiments carried out by irradiating at 340 and 485 nm, corresponding to the absorption maxima of (NAD)2 and adriamycin, respectively, clearly indicate that the process is primed by photoexcitation of adriamycin. The key step of the process is the redox reaction between (NAD)2 and adriamycin with formation of the semiquinone radical anion, identified by the EPR spectrum. The semiquinone is then oxidized back to adriamycin by oxygen with formation of the superoxide radical.     

NAD+ kinase--a review

NAD+ kinase catalyzes the only (known) biochemical reaction leading to the production of NADP+ from NAD+. Most evidence indicates it is found in the cytoplasm, but reports of its presence in (other) cell bodies can not be discounted. Viewed as a protein, our knowledge of NADK composition and architecture is rudimentary. Though recognized as a large multimeric protein, no agreement is evident for the molecular weight (Mr = approximately 4-65 X 10(4] of the native protein. Is calmodulin an integral subunit of (some, all) NAD+ kinases (analogous to phosphorylase kinase in skeletal muscle)? Or is it an external modulator? Consensus is evident that a subunit of molecular weight 30-35 X 10(3) is a component of the mammalian and yeast kinase. In one case (rabbit liver) two types of subunits are reported to give rise to oligomers differing in molecular weight and catalytic activities. Viewed as an enzyme it is not known why such a complex aggregate is needed for what might otherwise appear to a routine phosphorylation reaction. Rapid equilibrium random (for pigeon liver and C. utilis preparations) and ping-pong (for A. vinelandii kinase) mechanisms have been proposed for the reaction, with multiple reactant binding sites indicated for the random cases. From the perspective of enzyme modulation, the demonstration that green plant and sea urchin egg kinases are targets for calmodulin regulation by intracellular Ca2+ links NADP+ production in these sources to the multi-level discriminatory control functions inherent to this Ca2+-protein complex. Significant questions arise from the results of various investigators considered in this review. These queries offer fertile ground for the selective design of key experiments directed to a better understanding of NAD+ kinase function and pyridine nucleotide biochemistry.     

Compartmentation of NAD+-dependent signalling

NAD(+) plays central roles in energy metabolism as redox carrier. Recent research has identified important signalling functions of NAD(+) that involve its consumption. Although NAD(+) is synthesized mainly in the cytosol, nucleus and mitochondria, it has been detected also in vesicular and extracellular compartments. Three protein families that consume NAD(+) in signalling reactions have been characterized on a molecular level: ADP-ribosyltransferases (ARTs), Sirtuins (SIRTs), and NAD(+) glycohydrolases (NADases). Members of these families serve important regulatory functions in various cellular compartments, e.g., by linking the cellular energy state to gene expression in the nucleus, by regulating nitrogen metabolism in mitochondria, and by sensing tissue damage in the extracellular compartment. Distinct NAD(+) pools may be crucial for these processes. Here, we review the current knowledge about the compartmentation and biochemistry of NAD(+)-converting enzymes that control NAD(+) signalling.     

Manipulation of a nuclear NAD+ salvage pathway delays aging without altering steady-state NAD+ levels

Yeast deprived of nutrients exhibit a marked life span extension that requires the activity of the NAD(+)-dependent histone deacetylase, Sir2p. Here we show that increased dosage of NPT1, encoding a nicotinate phosphoribosyltransferase critical for the NAD(+) salvage pathway, increases Sir2-dependent silencing, stabilizes the rDNA locus, and extends yeast replicative life span by up to 60%. Both NPT1 and SIR2 provide resistance against heat shock, demonstrating that these genes act in a more general manner to promote cell survival. We show that Npt1 and a previously uncharacterized salvage pathway enzyme, Nma2, are both concentrated in the nucleus, indicating that a significant amount of NAD(+) is regenerated in this organelle. Additional copies of the salvage pathway genes, PNC1, NMA1, and NMA2, increase telomeric and rDNA silencing, implying that multiple steps affect the rate of the pathway. Although SIR2-dependent processes are enhanced by additional NPT1, steady-state NAD(+) levels and NAD(+)/NADH ratios remain unaltered. This finding suggests that yeast life span extension may be facilitated by an increase in the availability of NAD(+) to Sir2, although not through a simple increase in steady-state levels. We propose a model in which increased flux through the NAD(+) salvage pathway is responsible for the Sir2-dependent extension of life span.     

Pathway analysis of NAD+ metabolism

NAD(+) is well known as a crucial cofactor in the redox balance of metabolism. Moreover, NAD(+) is degraded in ADP-ribosyl transfer reactions, which are important components of multitudinous signalling reactions. These include reactions linked to DNA repair and aging. In the present study, using the concept of EFMs (elementary flux modes), we established all of the potential routes in a network describing NAD(+) biosynthesis and degradation. All known biosynthetic pathways, which include de novo synthesis starting from tryptophan as well as the classical Preiss-Handler pathway and NAD(+) synthesis from other vitamin precursors, were detected as EFMs. Moreover, several EFMs were found that degrade NAD(+), represent futile cycles or have other functionalities. The systematic analysis and comparison of the networks specific for yeast and humans document significant differences between species with regard to the use of precursors, biosynthetic routes and NAD(+)-dependent signalling.     

Sirtuin:依赖NAD+的去乙酰化酶

组蛋白的乙酰化一去乙酰化修饰在基因表达调控中起重要作用。参与去乙酰化的酶除了经典的Ⅰ类和Ⅱ类组蛋白去乙酰化酶(histone deacetylase,HDAC),还有比较特殊的Ⅲ类HDAC——Sirnlin,其活性依赖于NAD^ 。酵母的Sirtuin——Sir2在交配型基因沉默、端粒区基因沉默、rDNA沉默中起重要作用．还可能参与长寿与衰老的调节。在人类,Sirtuin的底物是组蛋白、各种转录因子如p53、FOXO、NF—KB、乙酰化酶如D300和其他的各种功能蛋白质。根据底物特点推测,人类Sirtuin蛋白的生理功能可能一方面是参与调节细胞在应激条件下的存活与死亡的平衡,另一方面是参与代谢的调节。     

Threonine 188 is critical for interaction with NAD+ in human NAD+-dependent 15-hydroxyprostaglandin dehydrogenase

NAD+-dependent 15-hydroxyprostaglandin dehydrogenase (15-PGDH) is the key enzyme in the inactivation pathway of prostaglandins. It is a member of the short-chain dehydrogenase family of enzymes. A relatively conserved threonine residue corresponding to threonine 188 of 15-PGDH is proposed to be involved in the interaction with the carboxamide group of NAD+. Site-directed mutagenesis was used to examine the important role of this residue. Threonine 188 was changed to alanine (T188A), serine (T188S) or tyrosine (T188Y) and the mutant proteins were expressed in E. coli. Western blot analysis showed that the expression levels of mutant proteins were similar to that of the wild type protein. Mutants T188A and T188Y were found to be inactive. Mutant T188S still retained substantial activity and the Km value for PGE2 was similar to the wild enzyme; however, the Km value for NAD+ was increased over 100 fold. These results suggest that threonine 188 is critical for interaction with NAD+ and contributes to the full catalytic activity of 15-PGDH.     

Mg2+-induced conformational changes in the btuB riboswitch from E. coli

Mg²⁺ has been shown to modulate the function of riboswitches by facilitating the ligand-riboswitch interactions. The btuB riboswitch from Escherichia coli undergoes a conformational change upon binding to its ligand, coenzyme B₁₂ (adenosyl-cobalamine, AdoCbl), and down-regulates the expression of the B₁₂ transporter protein BtuB in order to control the cellular levels of AdoCbl. Here, we discuss the structural folding attained by the btuB riboswitch from E. coli in response to Mg²⁺ and how it affects the ligand binding competent conformation of the RNA. The btuB riboswitch notably adopts different conformational states depending upon the concentration of Mg²⁺. With the help of in-line probing, we show the existence of at least two specific conformations, one being achieved in the complete absence of Mg²⁺ (or low Mg²⁺ concentration) and the other appearing above ∼0.5 mM Mg²⁺. Distinct regions of the riboswitch exhibit different dissociation constants toward Mg²⁺, indicating a stepwise folding of the btuB RNA. Increasing the Mg²⁺ concentration drives the transition from one conformation toward the other. The conformational state existing above 0.5 mM Mg²⁺ defines the binding competent conformation of the btuB riboswitch which can productively interact with the ligand, coenzyme B₁₂, and switch the RNA conformation. Moreover, raising the Mg²⁺ concentration enhances the ratio of switched RNA in the presence of AdoCbl. The lack of a AdoCbl-induced conformational switch experienced by the btuB riboswitch in the absence of Mg²⁺ indicates a crucial role played by Mg²⁺ for defining an active conformation of the riboswitch.     

Conformational capture of the SAM-II riboswitch

Riboswitches are gene regulation elements in mRNA that function by specifically responding to metabolites. Although the metabolite-bound states of riboswitches have proven amenable to structure determination efforts, knowledge of the structural features of riboswitches in their ligand-free forms and their ligand-response mechanisms giving rise to regulatory control is lacking. Here we explore the ligand-induced folding process of the S-adenosylmethionine type II (SAM-II) riboswitch using chemical and biophysical methods, including NMR and fluorescence spectroscopy, and single-molecule fluorescence imaging. The data reveal that the unliganded SAM-II riboswitch is dynamic in nature, in that its stem-loop element becomes engaged in a pseudoknot fold through base-pairing with nucleosides in the 3' overhang containing the Shine-Dalgarno sequence. Although the pseudoknot structure is highly transient in the absence of its ligand, S-adenosylmethionine (SAM), it becomes conformationally restrained upon ligand recognition, through a conformational capture mechanism. These insights provide a molecular understanding of riboswitch dynamics that shed new light on the mechanism of riboswitch-mediated translational regulation.     

Metabolism of NAD+ in the nuclei of human placenta

It has long been known that the major function of NAD+ is as an electron carrier in various biological oxidation-reduction systems. From many papers it is evident that NAD+ is involved as substrate in ADP-ribosylation reactions. We have focused our attention on two chromatin enzymes: NMN-adenylyltransferase that catalyzes reversible synthesis of NAD+ utilizing ATP and NMN, and poly(ADP-ribose)polymerase that covalently modifies nucleosomal proteins through poly ADP-ribosylation reactions. Here we provided evidence of these activities in a system of isolated nuclei from human placenta. The data presented in this report show that purified nuclei might be useful to study the nuclear location of these enzymes and their reciprocal interactions.     

Plasmodium falciparum Sir2 is an NAD+-dependent deacetylase and an acetyllysine-dependent and acetyllysine-independent NAD+ glycohydrolase

Sirtuins are NAD (+)-dependent enzymes that deacetylate a variety of cellular proteins and in some cases catalyze protein ADP-ribosyl transfer. The catalytic mechanism of deacetylation is proposed to involve an ADPR-peptidylimidate, whereas the mechanism of ADP-ribosyl transfer to proteins is undetermined. Herein we characterize a Plasmodium falciparum sirtuin that catalyzes deacetylation of histone peptide sequences. Interestingly, the enzyme can also hydrolyze NAD (+). Two mechanisms of hydrolysis were identified and characterized. One is independent of acetyllysine substrate and produces alpha-stereochemistry as established by reaction of methanol which forms alpha-1- O-methyl-ADPR. This reaction is insensitive to nicotinamide inhibition. The second solvolytic mechanism is dependent on acetylated peptide and is proposed to involve the imidate to generate beta-stereochemistry. Stereochemistry was established by isolation of beta-1- O-methyl-ADPR when methanol was added as a cosolvent. This solvolytic reaction was inhibited by nicotinamide, suggesting that nicotinamide and solvent compete for the imidate. These findings establish new reactions of wildtype sirtuins and suggest possible mechanisms for ADP-ribosylation to proteins. These findings also illustrate the potential utility of nicotinamide as a probe for mechanisms of sirtuin-catalyzed ADP-ribosyl transfer.