Metal ion binding and enzymatic mechanism of Methanococcus jannaschii RNase HII

RNase H degrades the RNA moiety in DNA:RNA hybrid in a divalent metal ion dependent manner. It is essential to understand the role of metal ion in enzymatic mechanism. One of the key points in this study is how many metal ions are involved in the enzyme catalysis. Accordingly, either one-metal binding mechanism or two-metal binding mechanism is proposed. We have studied the thermodynamic properties of four metal ions (Mg(2+), Mn(2+), Ca(2+), and Ba(2+)) binding to Methanococcus jannaschii RNase HII using isothermal titration calorimetry. All of the four metal ions were found to bind Mj RNase HII with 1:1 stoichiometry in the absence of substrate. Together with enzymatic activity assay data, we propose that only one metal ion binding to the enzyme in catalytic process. We also studied the pH dependence of metal binding and enzyme activity and found that at pH 6.5, Mg(2+) did not bind to the enzyme without the substrate but still activated the enzyme to about 2% of its maximum activity (in 10 mM Mn(2+) at pH 8). This implies that the substrate may also be incorporated in metal ion binding and help to position the metal ion. To find which acidic residues correspond to metal ion binding, we also studied the binding thermodynamics and enzymatic activity assay of four mutants: D7N, E8Q, D112N, and D149N in the presence of Mn(2+). The thermodynamic parameters are least affected for the D149N mutant, which has a very low enzymatic activity. This indicates that Asp149 is essential for the enzymatic activity. On the basis of all these observations, we suggest a metal binding model in which D7, E8, and D112 bind the metal ion and D149 activates a water molecule to attack the P-O bond in the RNA chain of the substrate.     

Multiple ribonuclease H-encoding genes in the Caenorhabditis elegans genome contrasts with the two typical ribonuclease H-encoding genes in the human genome

Database searches of the Caenorhabditis elegans and human genomic DNA sequences revealed genes encoding ribonuclease H1 (RNase H1) and RNase H2 in each genome. The human genome contains a single copy of each gene, whereas C. elegans has four genes encoding RNase H1-related proteins and one gene for RNase H2. By analyzing the mRNAs produced from the C. elegans genes, examining the amino acid sequence of the predicted protein, and expressing the proteins in Esherichia coli we have identified two active RNase H1-like proteins. One is similar to other eukaryotic RNases H1, whereas the second RNase H (rnh-1.1) is unique. The rnh-1.0 gene is transcribed as a dicistronic message with three dsRNA-binding domains; the mature mRNA is transspliced with SL2 splice leader and contains only one dsRNA-binding domain. Formation of RNase H1 is further regulated by differential cis-splicing events. A single rnh-2 gene, encoding a protein similar to several other eukaryotic RNase H2L's, also has been examined. The diversity and enzymatic properties of RNase H homologues are other examples of expansion of protein families in C. elegans. The presence of two RNases H1 in C. elegans suggests that two enzymes are required in this rather simple organism to perform the functions that are accomplished by a single enzyme in more complex organisms. Phylogenetic analysis indicates that the active C. elegans RNases H1 are distantly related to one another and that the C. elegans RNase H1 is more closely related to the human RNase H1. The database searches also suggest that RNase H domains of LTR-retrotransposons in C. elegans are quite unrelated to cellular RNases H1, but numerous RNase H domains of human endogenous retroviruses are more closely related to cellular RNases H.     

RNase HIII from Chlamydophila pneumoniae can efficiently cleave double-stranded DNA carrying a chimeric ribonucleotide in the presence of manganese

Two ribonuclease Hs (RNase Hs) have been found in Chlamydophila pneumoniae, CpRNase HII and CpRNase HIII. This work is the first report that CpRNase HIII can efficiently cleave DNA-rN(1) -DNA/DNA (rN(1) , monoribonucleotide) in vitro in the presence of Mn(2+) , whereas the enzymatic activity of CpRNase HII on the same substrate was inhibited by Mn(2+) and dependent on Mg(2+) . However, the ability of both CpRNase Hs to cleave other alternative substrates (RNA/DNA hybrids and Okazaki-like substrates), was insensitive to the divalent ions changes, suggesting that high concentrations of Mn(2+) specifically repressed the ability of CpRNase HII to cleave DNA-rN(1) -DNA/DNA but activated this function in CpRNase HIII. Further in vivo experiments showed that the CpRNase HII complementation of Escherichia coli rnh(-) mutations in an Mg(2+) environment was suppressed by Mn(2+) . In contrast, Mn(2+) was indispensable for CpRNase HIII to complement the same mutations. Further, the cell growth inhibition and the genomic DNA sensitivity to alkali in the bacterial strain lacking RNase HII activity could be relieved by functional CpRNase HII or HIII with its compatible ion. Therefore, CpRNase HIII can execute cleavage activity on DNA-rN(1) -DNA/DNA under a Mn(2+) -rich environment and may function as a substitute for CpRNase HII under special physiological states.     

Properties of cloned and expressed human RNase H1.

We have characterized cloned His-tag human RNase H1. The activity of the enzyme exhibited a bell-shaped response to divalent cations and pH. The optimum conditions for catalysis consisted of 1 mM Mg(2+) and pH 7-8. In the presence of Mg(2+), Mn(2+) was inhibitory. Human RNase H1 shares many enzymatic properties with Escherichia coli RNase H1. The human enzyme cleaves RNA in a DNA-RNA duplex resulting in products with 5'-phosphate and 3'-hydroxy termini, can cleave overhanging single strand RNA adjacent to a DNA-RNA duplex, and is unable to cleave substrates in which either the RNA or DNA strand has 2' modifications at the cleavage site. Human RNase H1 binds selectively to "A-form"-type duplexes with approximately 10-20-fold greater affinity than that observed for E. coli RNase H1. The human enzyme displays a greater initial rate of cleavage of a heteroduplex-containing RNA-phosphorothioate DNA than an RNA-DNA duplex. Unlike the E. coli enzyme, human RNase H1 displays a strong positional preference for cleavage, i.e. it cleaves between 8 and 12 nucleotides from the 5'-RNA-3'-DNA terminus of the duplex. Within the preferred cleavage site, the enzyme displays modest sequence preference with GU being a preferred dinucleotide. The enzyme is inhibited by single-strand phosphorothioate oligonucleotides and displays no evidence of processivity. The minimum RNA-DNA duplex length that supports cleavage is 6 base pairs, and the minimum RNA-DNA "gap size" that supports cleavage is 5 base pairs.     

Archaeoglobus fulgidus RNase HII in DNA replication: enzymological functions and activity regulation via metal cofactors

RNA primer removal during DNA replication is dependent on ribonucleotide- and structure-specific RNase H and FEN-1 nuclease activities. A specific RNase H involved in this reaction has long been sought. RNase HII is the only open reading frame in Archaeoglobus fulgidus genome, while multiple RNases H exist in eukaryotic cells. Data presented here show that RNase HII from A. fulgidus (aRNase HII) specifically recognizes RNA-DNA junctions and generates products suited for the FEN-1 nuclease, indicating its role in DNA replication. Biochemical characterization of aRNase HII activity in the presence of various divalent metal ions reveals a broad metal tolerance with a preference for Mg(2+) and Mn(2+). Combined mutagenesis, biochemical competitions, and metal-dependent activity assays further clarify the functions of the identified amino acid residues in substrate binding or catalysis, respectively. These experiments also reveal that Asp129 form a second-metal binding site, and thus contribute to activity attenuation.     

Catalytic mechanism of endonuclease v: a catalytic and regulatory two-metal model

The enzyme endonuclease V initiates repair of deaminated DNA bases by making an endonucleolytic incision on the 3' side one nucleotide from a base lesion. In this study, we have used site-directed mutagenesis to characterize the role of the highly conserved residues D43, E89, D110, and H214 in Thermotoga maritima endonuclease V catalysis. DNA cleavage and Mn(2+)-rescue analysis suggest that amino acid substitutions at D43 impede the enzymatic activity severely while mutations at E89 and D110 may be tolerated. Mutations at H214 yield enzyme that maintains significant DNA cleavage activity. The H214D mutant exhibits little change in substrate specificity or DNA cleavage kinetics, suggesting the exchangeability between His and Asp at this site. DNA binding analysis implicates the involvement of the four residues in metal binding. Mn(2+)-mediated cleavage of inosine-containing DNA is stimulated by the addition of Ca(2+), a metal ion that does not support catalysis. The effects of Mn(2+) on Mg(2+)-mediated DNA cleavage show a complexed initial stimulatory and later inhibitory pattern. The data obtained from the dual metal ion analyses lead to the notion that two metal ions are involved in endonuclease V-mediated catalysis. A catalytic and regulatory two-metal model is proposed.     

Purification and characterization of a mammalian endo-exonuclease.

An endo-exonuclease has been purified from cultured monkey (CV-1) cells. The enzyme which was purified to near homogeneity to be a 65 kDa monomeric protein. The single-strand DNase activity is endonucleolytic and nonprocessive, whereas the double-strand DNase activity is exonucleolytic and processive. The enzyme was also found to have RNase activity using poly-rA as substrate. The pH optimum for ss-DNase is 8 and for ds-DNase it is 7.5. Both DNase activities require a divalent metal ion (Mg2+, Mn2+, Ca2+, Zn2+) for activity and exhibit the same kinetics of heat inactivation. The purified protein binds to and cleaves a synthetic Holliday junction substrate. The overall enzymatic characteristics of the mammalian protein are very similar to the putative recombination endo-exonucleases purified from Neurospora crassa, Aspergillus nidulans and Saccharomyces cerevisiae.     

Mutational analysis of the nuclease domain of Escherichia coli ribonuclease III. Identification of conserved acidic residues that are important for catalytic function in vitro

The ribonuclease III superfamily represents a structurally distinct group of double-strand-specific endonucleases with essential roles in RNA maturation, RNA decay, and gene silencing. Bacterial RNase III orthologs exhibit the simplest structures, with an N-terminal nuclease domain and a C-terminal double-stranded RNA-binding domain (dsRBD), and are active as homodimers. The nuclease domain contains conserved acidic amino acids, which in Escherichia coli RNase III are E38, E41, D45, E65, E100, D114, and E117. On the basis of a previously reported crystal structure of the nuclease domain of Aquifex aeolicus RNase III, the E41, D114, and E117 side chains of E. coli RNase III are expected to be coordinated to a divalent metal ion (Mg(2+) or Mn(2+)). It is shown here that the RNase III[E41A] and RNase III[D114A] mutants exhibit catalytic activities in vitro in 10 mM Mg(2+) buffer that are comparable to that of the wild-type enzyme. However, at 1 mM Mg(2+), the activities are significantly lower, which suggests a weakened affinity for metal. While RNase III[E41A] and RNase III[D114A] have K(Mg) values that are approximately 2.8-fold larger than the K(Mg) of RNase III (0.46 mM), the RNase III[E41A/D114A] double mutant has a K(Mg) of 39 mM, suggesting a redundant function for the two side chains. RNase III[E38A], RNase III[E65A], and RNase III[E100A] also require higher Mg(2+) concentrations for optimal activity, with RNase III[E100A] exhibiting the largest K(Mg). RNase III[D45A], RNase III[D45E], and RNase III[D45N] exhibit negligible activities, regardless of the Mg(2+) concentration, indicating a stringent functional requirement for an aspartate side chain. RNase III[D45E] activity is partially rescued by Mn(2+). The potential functions of the conserved acidic residues are discussed in the context of the crystallographic data and proposed catalytic mechanisms.     

Mechanism of action of Escherichia coli ribonuclease III. Stringent chemical requirement for the glutamic acid 117 side chain and Mn2+ rescue of the Glu117Asp mutant

Escherichia coli ribonuclease III (EC 3.1.24) is a double-strand- (ds-) specific endoribonuclease involved in the maturation and decay of cellular, phage, and plasmid RNAs. RNase III is a homodimer and requires Mg(2+) to hydrolyze phosphodiesters. The RNase III polypeptide contains an N-terminal catalytic (nuclease) domain which exhibits eight highly conserved acidic residues, at least one of which (Glu117) is important for phosphodiester hydrolysis but not for substrate binding [Li and Nicholson (1996) EMBO J. 15, 1421-1433]. To determine the side chain requirements for activity, Glu117 was changed to glutamine or aspartic acid. The mutant proteins were purified as (His)(6)-tagged species, and both exhibited normal homodimeric behavior as shown by chemical cross-linking. The Glu117Gln mutant is unable to cleave substrate in vitro under all tested conditions but can bind substrate. The Glu117Asp mutant also is defective in cleavage while able to bind substrate. However, low level activity is observed at extended reaction times and high enzyme concentrations, with an estimated catalytic efficiency approximately 15 000-fold lower than that of RNase III. The activity of the Glu117Asp mutant but not that of the Glu117Gln mutant can be greatly enhanced by substituting Mn(2+) for Mg(2+), with the catalytic efficiency of the Glu117Asp-Mn(2+) holoenzyme approximately 400-fold lower than that of the RNase III-Mn(2+) holoenzyme. For RNase III, a Mn(2+) concentration of 1 mM provides optimal activity, while concentrations >5 mM are inhibitory. In contrast, the Glu117Asp mutant is not inhibited by high concentrations of Mn(2+). Finally, high concentrations of Mg(2+) do not inhibit RNase III nor relieve the Mn(2+)-dependent inhibition. In summary, these experiments establish the stringent functional requirement for a precisely positioned carboxylic acid group at position 117 and reveal two classes of divalent metal ion binding sites on RNase III. One site binds either Mg(2+) or Mn(2+) and supports catalysis, while the other site is specific for Mn(2+) and confers inhibition. Glu117 is important for the function of both sites. The implications of these findings on the RNase III catalytic mechanism are discussed.     

Ribonuclease III cleavage of a bacteriophage T7 processing signal. Divalent cation specificity, and specific anion effects.

Escherichia coli ribonuclease III, purified to homogeneity from an overexpressing bacterial strain, exhibits a high catalytic efficiency and thermostable processing activity in vitro. The RNase III-catalyzed cleavage of a 47 nucleotide substrate (R1.1 RNA), based on the bacteriophage T7 R1.1 processing signal, follows substrate saturation kinetics, with a Km of 0.26 microM, and kcat of 7.7 min.-1 (37 degrees C, in buffer containing 250 mM potassium glutamate and 10 mM MgCl2). Mn2+ and Co2+ can support the enzymatic cleavage of the R1.1 RNA canonical site, and both metal ions exhibit concentration dependences similar to that of Mg2+. Mn2+ and Co2+ in addition promote enzymatic cleavage of a secondary site in R1.1 RNA, which is proposed to result from the altered hydrolytic activity of the metalloenzyme (RNase III 'star' activity), exhibiting a broadened cleavage specificity. Neither Ca2+ nor Zn2+ support RNase III processing, and Zn2+ moreover inhibits the Mg(2+)-dependent enzymatic reaction without blocking substrate binding. RNase III does not require monovalent salt for processing activity; however, the in vitro reactivity pattern is influenced by the monovalent salt concentration, as well as type of anion. First, R1.1 RNA secondary site cleavage increases as the salt concentration is lowered, perhaps reflecting enhanced enzyme binding to substrate. Second, the substitution of glutamate anion for chloride anion extends the salt concentration range within which efficient processing occurs. Third, fluoride anion inhibits RNase III-catalyzed cleavage, by a mechanism which does not involve inhibition of substrate binding.     

Purification and properties of magnesium- and manganese-dependent ribonucleases H from chick embryo

Two RNases H, Mg2+- and Mn2+-dependent RNases H, are present in extracts of chick embryo. These RNases H can be separated by phosphocellulose column chromatography. Mg2+-dependent RNase H was purified over 900-fold and Mn2+-dependent RNase H over 1,700-fold from chick embryo extracts. The molecular weight of the purified Mg2+-dependent RNase H was about 40,000 and of the Mn2+-dependent RNase H about 120,000, when estimated by gel filtration. Mg2+-dependent RNase H exhibits maximal activity at pH 9.5, and requires 15 to 20 mM Mg2+ for maximal activity, whereas Mn2+-dependent RNase H is most active at pH 8.5, and is maximally active at the concentration of 0.4 mM Mn2+, and has some activity with Mg2+. Both enzymes require a sulfhydryl reagent for maximal activity. Mn2+-dependent RNase H was inhibited by o-phenanthroline, pyrophosphate, and those polyamines tested, whereas Mg2+-dependent enzyme was not, although it was inhibited by NaF. Both RNases H liberate a mixture of oligonucleotides with 5'-phosphate and 3'-hydroxyl termini endonucleolytically.     

Two ribonucleases H from cultured plant cells.

Two forms of enzyme with ribonuclease H (RNase H) [EC 3.1.4.34] activities, have been partially purified from cultured plant cells, strain GD-2, derived from carrot root. One is an Mn2+-dependent RNase H, and the second is an Mg2+-dependent RNase H. These enzymes degrade RNA specifically in RNA-DNA hybrid structures. They were eluted at around 0.2 M and 0.4 M potassium chloride in phosphocellulose chromatography, and were further purified using blue Sepharose. Mg2+-dependent RNase H exhibits maximal activity at pH 9.0, and requires 10 to 15 mM Mg2+ for maximal activity, whereas the Mn2+-dependent enzyme is most active at pH 8.0, is maximally active at an Mn2+ concentration of 0.4 mM, and has some activity with Mg2+. Both enzymes require a sulfhydryl reagent for maximal activity. The enzymes liberate a mixture of oligonucleotides with 5'-phosphate and 3'-hydroxyl termini. The apparent molecular weight of the Mg2+-dependent RNase H was estimated to 18--20 X 10(4) and that of the Mn 2+- dependent RNase H was estimated to be 14 x 10(4) by gel filtration.     

Distinct roles of two Mg2+ binding sites in regulation of murine flap endonuclease-1 activities

Removal of flap DNA intermediates in DNA replication and repair by flap endonuclease-1 (FEN-1) is essential for mammalian genome integrity. Divalent metal ions, Mg(2+) or Mn(2+), are required for the active center of FEN-1 nucleases. However, it remains unclear as to how Mg(2+) stimulates enzymatic activity. In the present study, we systemically characterize the interaction between Mg(2+) and murine FEN-1 (mFEN-1). We demonstrate that Mg(2+) stimulates mFEN-1 activity at physiological levels but inhibits the activity at concentrations higher than 20 mM. Our data suggest that mFEN-1 exists as a metalloenzyme in physiological conditions and that each enzyme molecule binds two Mg(2+) ions. Binding of Mg(2+) to the M1 binding site coordinated by the D86 residue cluster enhances mFEN-1's capability of substrate binding, while binding of the metal to the M2 binding site coordinated by the D181 residue cluster induces conformational changes. Both of these steps are needed for catalysis. Weak, nonspecific Mg(2+) binding is likely responsible for the enzyme inhibition at high concentrations of the cation. Taken together, our results suggest distinct roles for two Mg(2+) binding sites in the regulation of mFEN-1 nuclease activities in a mode different from the "two-metal mechanism".     

Characterization of the protein kinase activity of TRPM7/ChaK1, a protein kinase fused to the transient receptor potential ion channel

Channel-kinase TRPM7/ChaK1 is a member of a recently discovered family of protein kinases called alpha-kinases that display no sequence homology to conventional protein kinases. It is an unusual bifunctional protein that contains an alpha-kinase domain fused to an ion channel. The TRPM7/ChaK1 channel has been characterized using electrophysiological techniques, and recent evidence suggests that it may play a key role in the regulation of magnesium homeostasis. However, little is known about its protein kinase activity. To characterize the kinase activity of TRPM7/ChaK1, we expressed the kinase catalytic domain in bacteria. ChaK1-cat is able to undergo autophosphorylation and to phosphorylate myelin basic protein and histone H3 on serine and threonine residues. The kinase is specific for ATP and cannot use GTP as a substrate. ChaK1-cat is insensitive to staurosporine (up to 0.1 mM) but can be inhibited by rottlerin. Because the kinase domain is physically linked to an ion channel, we investigated the effect of ions on ChaK1-cat activity. The kinase requires Mg(2+) (optimum at 4-10 mM) or Mn(2+) (optimum at 3-5 mM), with activity in the presence of Mn(2+) being 2 orders of magnitude higher than in the presence of Mg(2+). Zn(2+) and Co(2+) inhibited ChaK1-cat kinase activity. Ca(2+) at concentrations up to 1 mM did not affect kinase activity. Considering intracellular ion concentrations, our results suggest that, among divalent metal ions, only Mg(2+) can directly modulate TRPM7/ChaK1 kinase activity in vivo.