Inert chromium and cobalt complexes as probes of magnesium-dependent enzymes. Evaluation of the mechanistic role of the essential metal cofactor in Escherichia coli exonuclease III

Understanding the Thermodynamics of Magnesium Binding to RNA Structural Motifs

Divalent magnesium ions (Mg2+) serve a vital role in defining the structural and catalytic chemistry of a wide array of RNA molecules. The body of structural information on RNA motifs continues to expand and, in turn, the functional importance of Mg2+ is revealed. A combination of prior work on the structural characterization of magnesium binding ligands with inner- and outer-sphere coordination modes, with recorded experimental binding energies for inner- and outer-sphere contacts, demonstrates the relative affinity and thermodynamic hierarchy for these sites. In turn, these can be correlated with cellular concentrations of free available magnesium ions, allowing the prioritization of populating important functional sites and a correlation with physiological function. This paper summarizes some of the key results of that analysis and provides predictive rules for the affinity and role of newly identified Mg binding sites on complex RNA structures. The influence of crystal packing on magnesium binding to RNA motifs, relative to their solution form, is addressed and caveats made.

Ultrasensitive colorimetric aptasensor for Hg2+ detection using Exo-III assisted target recycling amplification and unmodified AuNPs as indicators

Facile and ultrasensitive detection of Hg²⁺ in water environment remains challenging. Exonuclease III (Exo-III)-assisted target recycling is one of the most popular amplification strategies. Although the magnesium (II) ions are widely acting as cofactors of Exo-III, we recognized that Mg²⁺ cofactors would strongly disturb the charge distribution on citrate-stablized gold nanoparticles (in the general sense, unmodified AuNPs) surface, thus generate false positive colorimetric signals. To address this issue, we first put forward the view that the cobalt (II) ions can function as the Exo-III cofactor and successfully construct a novel label-free colorimetric aptasensor for facile and ultrasensitive detection of Hg²⁺ using Hg²⁺-triggered Exo-III-assisted signal amplification and unmodified AuNPs as indicators. A hairpin-looped DNA probe was rationally designed with thymine-rich recognition termini and specifically recognized trace Hg²⁺ by a stable T-Hg²⁺-T structure. A blue-to-red color change of AuNPs with the addition of Hg²⁺ provided the quantitative detection of Hg²⁺ with a limit of detection of 0.2 nM and a linear working range from 0.5 nM to 5.0 nM. The whole testing time for one assay was approximately 40 min. Real water samples, even containing Hg²⁺ at 1 nM, could be determined by the aptasensor with recovery rates from 97% to 103%.

Advantage of being a dimer for Serratia marcescens endonuclease

The monomer and dimer of the bacterium Serratia marcescens endonuclease (SMnase) are each catalytically active, and the two subunits of the dimer function independently of each other. Nature, however, chooses the dimer form instead of the monomer. In order to explain this, we performed molecular dynamics (MD) simulations of both model-built complexes of a subunit of SMnase and the dimer with DNA in aqueous solution. We estimated the electrostatic binding energy, analyzed the distribution and dynamics of water around the complexes, identified water clusters in the protein, and related the dynamics of water to the protein's function. We find that the dimer form has an electrostatic advantage over the monomer to associate with DNA. Although Mg(2+) remains hexa-coordinated during the simulation, the binding pathway of DNA to Mg(2+) changes from inner-sphere binding in the monomer to outer-sphere in the dimer, which may be more energetically favorable. In addition, two water clusters in the active site of each monomer and in the dimer complex were identified and localized in two regions, named the "stabilizing" and "working" regions. Water in the "working" region in the dimer complex has larger fluctuations than that in the monomer.

Metal Ion Activation of S-Adenosylmethionine Decarboxylase Reflects Cation Charge Density

S-Adenosylmethionine decarboxylase from Escherichia coli is a pyruvoyl cofactor-containing enzyme that requires a metal cation for activity. We have found that the enzyme is activated by cations of varying charge and ionic radius, such as Li+, A13+, Tb3+, and Eu3+, as well as the divalent cations Mg2+, Mn2+, and Ca2+. All of the activating cations provide kcat values within 30-fold of one another, showing that the charge of the cation does not greatly influence the rate-limiting step for decarboxylase turnover. Cation concentrations for half-maximal activation decrease by >100-fold with each increment of increase in the cation charge, ranging from approximately 300 mM with Li+ to approximately 2 microM with trivalent lanthanide ions. The cation affinity is related to the charge/radius ratio of the ion for those ions with exchangeable first coordination sphere ligands. The exchange-inert cation Co(NH3)63+ activates in the presence of excess EDTA (and NH4+ does not activate), indicating that direct metal coordination to the protein or substrate is not required for activation. The binding of metal ions (monitored by changes in the protein tryptophan fluorescence) and enzyme activation are both cooperative with Hill coefficients as large as 4, the active site stoichiometry of this (alphabeta)4 enzyme. The Hill coefficients for Mg2+ binding and activation increase from 1 to approximately 4 as the KCl concentration increases, which is also observed with NaCl or KNO3; neither Na+ nor K+ activates the enzyme. The single tryptophan in the protein is located 16 residues from the carboxyl terminus of the pyruvoyl-containing alpha chain, in a 70-residue segment that is not present in metal ion independent AdoMet decarboxylases from other organisms. The results are consistent with allosteric metal ion activation of the enzyme, congruent with the role of the putrescine activator of the mammalian AdoMet decarboxylase.

Structural basis of catalysis by monometalated methionine aminopeptidase

Methionine aminopeptidase (MetAP) removes the amino-terminal methionine residue from newly synthesized proteins, and it is a target for the development of antibacterial and anticancer agents. Available x-ray structures of MetAP, as well as other metalloaminopeptidases, show an active site containing two adjacent divalent metal ions bridged by a water molecule or hydroxide ion. The predominance of dimetalated structures leads naturally to proposed mechanisms of catalysis involving both metal ions. However, kinetic studies indicate that in many cases, only a single metal ion is required for full activity. By limiting the amount of metal ion present during crystal growth, we have now obtained a crystal structure for a complex of Escherichia coli MetAP with norleucine phosphonate, a transition-state analog, and only a single Mn(II) ion bound at the active site in the position designated M1, and three related structures of the same complex that show the transition from the mono-Mn(II) form to the di-Mn(II) form. An unliganded structure was also solved. In view of the full kinetic competence of the monometalated MetAP, the much weaker binding constant for occupancy of the M2 site compared with the M1 site, and the newly determined structures, we propose a revised mechanism of peptide bond hydrolysis by E. coli MetAP. We also suggest that the crystallization of dimetalated forms of metallohydrolases may, in some cases, be a misleading experimental artifact, and caution must be taken when structures are generated to aid in elucidation of reaction mechanisms or to support structure-aided drug design efforts.

Identification of Single Mn2+ Binding Sites Required for Activation of the Mutant Proteins of E.coli RNase HI at Glu48 and/or Asp134 by X-ray Crystallography

Escherichia coli RNase HI has two Mn(2+)-binding sites. Site 1 is formed by Asp10, Glu48, and Asp70, and site 2 is formed by Asp10 and Asp134. Site 1 and site 2 have been proposed to be an activation site and an attenuation site, respectively. However, Glu48 and Asp134 are dispensable for Mn(2+)-dependent activity. In order to identify the Mn(2+)-binding sites of the mutant proteins at Glu48 and/or Asp134, the crystal structures of the mutant proteins E48A-RNase HI*, D134A-RNase HI*, and E48A/D134N-RNase HI* in complex with Mn(2+) were determined. In E48A-RNase HI*, Glu48 and Lys87 are replaced by Ala. In D134A-RNase HI*, Asp134 and Lys87 are replaced by Ala. In E48A/D134N-RNase HI*, Glu48 and Lys87 are replaced by Ala and Asp134 is replaced by Asn. All crystals had two or four protein molecules per asymmetric unit and at least two of which had detectable manganese ions. These structures indicated that only one manganese ion binds to the various positions around the center of the active-site pocket. These positions are different from one another, but none of them is similar to site 1. The temperature factors of these manganese ions were considerably larger than those of the surrounding residues. These results suggest that the first manganese ion required for activation of the wild-type protein fluctuates among various positions around the center of the active-site pockets. We propose that this fluctuation is responsible for efficient hydrolysis of the substrates by the protein (metal fluctuation model). The binding position of the first manganese ion is probably forced to shift to site 1 or site 2 upon binding of the second manganese ion.

Chemical nucleases

Substantial progress is being made in the synthesis of functional mimics of metallonuclease enzymes, although a comparison with enzyme-promoted rates of reaction shows considerable room for future improvement. Improved ligand design allows facile substrate binding to metal ion catalysts, while maintaining the stability of the metal complex. The execution of double-strand cleavage of DNA under hydrolytic conditions has been reported and new levels of activity achieved. Finally, considerable progress has been made in identifying the molecular determinants for site-selective cleavage of RNA (in particular) and the design of ligands to achieve targeted recognition and cleavage.

Characterization of a multi-functional metal-mediated nuclease by MALDI-TOF mass spectrometry

Mass spectrometric analysis of reaction products allows simultaneous characterization of activities mediated by multifunctional enzymes. By use of MALDI-TOF mass spectrometry, the relative influence of magnesium and manganese promoted exonuclease and phosphatase activities of Esherichia coli exonuclease III have been quantitatively measured, offering a rapid and sensitive alternative to radioactivity quantification and gel electrophoresis procedures for determination of reaction rate constants. Manganese is found to promote higher levels of exonuclease activity, which could be a source of mutagenic effects if this ion were selected as the natural cofactor. Several potential applications of these methods to quantitative studies of DNA repair chemistry are also described.

Rapid and direct sequencing of double-stranded DNA using exonuclease III and MALDI-TOF MS

Application of MALDI-TOF MS to direct sequencing of dsDNA substrates is demonstrated using a strategy that employs exonuclease III digestion of a target sequence. Experimental conditions for exonuclease III have been optimized for this application, including addition of essential divalent metal ion cofactors. A short cation-exchange column was designed to provide efficient sample cleanup and overcome major problems arising from salt interference.

Cation hexaammines are selective and potent inhibitors of the CorA magnesium transport system

Cation hexaammines and related compounds are chemically stable analogs of the hydrated form of cations, particularly Mg(2+). We tested the ability of several of these compounds to inhibit transport by the CorA or MgtB Mg(2+) transport systems or the PhoQ receptor kinase for Mg(2+) in Salmonella typhimurium. Cobalt(III)-, ruthenium(II)-, and ruthenium(III)-hexaammines were potent inhibitors of CorA-mediated influx. Cobalt(III)- and ruthenium(III)chloropentaammines were slightly less potent inhibitors of CorA. The compounds inhibited uptake by the bacterial S. typhimurium CorA and by the archaeal Methanococcus jannaschii CorA, which bear only 12% identity in the extracellular periplasmic domain. Cation hexaammines also inhibited growth of S. typhimurium strains dependent on CorA for Mg(2+) uptake but not of isogenic strains carrying a second Mg(2+) uptake system. In contrast, hexacyano-cobaltate(III) and ruthenate(II)- and nickel(II)hexaammine had little effect on uptake. The inhibition by the cation hexaammines was selective for CorA because none of the compounds had any effect on transport by the MgtB P-type ATPase Mg(2+) transporter or the PhoQ Mg(2+) receptor kinase. These results demonstrate that cation hexaammines are potent and highly selective inhibitors of the CorA Mg(2+) transport system and further indicate that the initial interaction of the CorA transporter is with a fully hydrated Mg(2+) cation.

The role of Mg2+ and specific amino acid residues in the catalytic reaction of the major human abasic endonuclease: new insights from EDTA-resistant incision of acyclic abasic site analogs and site-directed mutagenesis

Ape1, the major protein responsible for excising apurinic/apyrimidinic (AP) sites from DNA, cleaves 5' to natural AP sites via a hydrolytic reaction involving Mg2+. We report here that while Ape1 incision of the AP site analog tetrahydrofuran (F-DNA) was approximately 7300-fold reduced in 4 mM EDTA relative to Mg2+, cleavage of ethane (E-DNA) and propane (P-DNA) acyclic abasic site analogs was only 20 and 30-fold lower, respectively, in EDTA compared to Mg2+. This finding suggests that the primary role of the metal ion is to promote a conformational change in the ring-containing abasic DNA, priming it for enzyme-mediated hydrolysis. Mutating the proposed metal-coordinating residue E96 to A or Q resulted in a approximately 600-fold reduced incision activity for both P and F-DNA in Mg2+compared to wild-type. These mutants, while retaining full binding activity for acyclic P-DNA, were unable to incise this substrate in EDTA, pointing to an alternative or an additional function for E96 besides Mg2+-coordination. Other residues proposed to be involved in metal coordination were mutated (D70A, D70R, D308A and D308S), but displayed a relatively minor loss of incision activity for F and P-DNA in Mg2+, indicating a non-essential function for these amino acid residues. Mutations at Y171 resulted in a 5000-fold reduced incision activity. A Y171H mutant was fourfold less active than a Y171F mutant, providing evidence that Y171 does not operate as the proton donor in catalysis and that the additional role of E96 may be in establishing the appropriate active site environment via a hydrogen-bonding network involving Y171. D210A and D210N mutant proteins exhibited a approximately 25,000-fold reduced incision activity, indicating a critical role for this residue in the catalytic reaction. A D210H mutant was 15 to 20-fold more active than the mutants D210A or D210N, establishing that D210 likely operates as the leaving group proton donor.

Microbial magnesium transport: unusual transporters searching for identity

Mg2+ is unique among biological cations because of its charge density and solution chemistry. This is abundantly reflected in its transport systems, studied primarily in Salmonella typhimurium. The constitutively expressed CorA transport system is the primary Mg2+ influx pathway for the Bacteria and the Archaea. Its structure of a large N-terminal soluble periplasmic domain with three transmembrane segments at the C-terminus is unique among membrane carriers, and its protein sequence bears no resemblance to other known proteins. The MgtE transport system can also mediate Mg2+ uptake, but whether this is its primary function is not known. MgtE also lacks homology to other known proteins. In contrast, the MgtA and MgtB Mg2+ transport systems of enteric bacteria are P-type ATPases by sequence homology, mediating Mg2+ influx with, rather than against, the Mg2+ electrochemical gradient. They are closely related to mammalian Ca2+-ATPases. Expression of MgtA and MgtB is under the control of the PhoPQ two-component regulatory system, important in bacterial virulence. In S. typhimurium, MgtB is encoded by a two-gene operon mgtCB; the function of the MgtC protein is unknown, and it lacks close homologues. The ligand for the PhoQ membrane sensor kinase is Mg2+ and, at decreased extracellular Mg2+ concentrations, transcription of mgtA and mgtCB are enormously induced. All three genes are also induced upon S. typhimurium invasion of epithelial or macrophage cells. Mutation of these genes has no effect on invasion efficiency, but an insertion in mgtC renders S. typhimurium essentially avirulent in the mouse. The physiological roles of the known Mg2+ transport systems are not yet completely defined. Nonetheless, the singular sequence and apparent structure of the CorA and MgtE transport proteins, the complex regulation of MgtA, MgtB and MgtC and their involvement in pathogenesis suggests that further study will be rewarding.

A unique mechanism for RNA catalysis: the role of metal cofactors in hairpin ribozyme cleavage

BACKGROUND

Ribozymes are biological catalysts that promote the hydrolysis and transesterification of phosphate diesters of RNA. They typically require divalent magnesium ions for activation, although it has proven difficult to differentiate structural from catalytic roles for the magnesium ions and to identify the molecular mechanism of catalysis. Direct inner-sphere coordination is usually invoked in the catalytic step, although there is no evidence to support the generality of such a pathway for all ribozymes.

RESULTS

We studied the catalytic pathway for the hairpin class of ribozyme. The substitutionally inert transition metal complex cobalt hexaammine [Co(NH3)6(3+)] was shown to be as active as Mg2+(aq) in promoting hairpin ribozyme activity, demonstrating that inner-sphere pathways are not used by this class of ribozyme. These results were confirmed by studies with Rp- and Sp-phosphorothioate substrate analogs which show a similar reactivity to that of the native substrate towards the magnesium-activated ribozyme. Monovalent cations enhance the activity of Co(NH3)6(3+)-promoted reactions, but inhibit Mg(2+)-activated catalysis, demonstrating a requirement for hydrated cations at several key sites in the ribozyme.

CONCLUSIONS

These results provide clear support for a model of RNA catalysis that does not involve direct coordination of magnesium to the phosphate ester, nor activation of a bound water molecule. A mechanism in which catalysis is carried out by functional groups on the RNA ribozyme itself is possible; such functional groups are likely to have pKa values that are appropriate for carrying out this catalysis. The metal cofactor would then serve to define the architecture of the catalytic pocket and contribute to the stabilization of transient species, as has been described earlier. Hydrolytic pathways in nucleic acid reactions are apparently more diverse than was previously thought, and the hairpin ribozyme falls into a mechanistically distinct class from the Tetrahymena and the hammerhead ribozymes.