Lack of correlation between binding of Eco RII methyltransferase to DNA duplexes containing mismatches and the promotion of C to T mutations

The cytosine methyltransferases (MTases) M. HhaIand M. HpaII bind substrates in which the target cytosine is replaced by uracil or thymine, i.e. DNA containing a U:G or a T:G mismatch. We have extended this observation to the EcoRII MTase (M. EcoRII) and determined the apparent K_d for binding. Using a genetic assay we have also tested the possibility that MTase binding to U:G mismatches may interfere with repair of the mismatches and promote C:G to T:A mutations. We have compared two mutants of M. EcoRII that are defective for catalysis by the wild-type enzyme for their ability to bind DNA containing U:G or T:G mismatches and for their ability to promote C to T mutations. We find that although all three proteins are able to bind DNAs with mismatches, only the wild-type enzyme promotes C:G to T:A mutations in vivo. Therefore, the ability of M. EcoRII to bind U:G mismatched duplexes is not sufficient for their mutagenic action in cells. Received: 14 November 1996 / Accepted: 17 February 1997     

Lack of correlation between binding of Eco RII methyltransferase to DNA duplexes containing mismatches and the promotion of C to T mutations

The cytosine methyltransferases (MTases) M. HhaIand M. HpaII bind substrates in which the target cytosine is replaced by uracil or thymine, i.e. DNA containing a U:G or a T:G mismatch. We have extended this observation to the EcoRII MTase (M. EcoRII) and determined the apparent K_d for binding. Using a genetic assay we have also tested the possibility that MTase binding to U:G mismatches may interfere with repair of the mismatches and promote C:G to T:A mutations. We have compared two mutants of M. EcoRII that are defective for catalysis by the wild-type enzyme for their ability to bind DNA containing U:G or T:G mismatches and for their ability to promote C to T mutations. We find that although all three proteins are able to bind DNAs with mismatches, only the wild-type enzyme promotes C:G to T:A mutations in vivo. Therefore, the ability of M. EcoRII to bind U:G mismatched duplexes is not sufficient for their mutagenic action in cells.     

Cytosine-to-Uracil Deamination by SssI DNA Methyltransferase

The prokaryotic DNA(cytosine-5)methyltransferase M.SssI shares the specificity of eukaryotic DNA methyltransferases (CG) and is an important model and experimental tool in the study of eukaryotic DNA methylation. Previously, M.SssI was shown to be able to catalyze deamination of the target cytosine to uracil if the methyl donor S-adenosyl-methionine (SAM) was missing from the reaction. To test whether this side-activity of the enzyme can be used to distinguish between unmethylated and C5-methylated cytosines in CG dinucleotides, we re-investigated, using a sensitive genetic reversion assay, the cytosine deaminase activity of M.SssI. Confirming previous results we showed that M.SssI can deaminate cytosine to uracil in a slow reaction in the absence of SAM and that the rate of this reaction can be increased by the SAM analogue 5’-amino-5’-deoxyadenosine. We could not detect M.SssI-catalyzed deamination of C5-methylcytosine (^m5C). We found conditions where the rate of M.SssI mediated C-to-U deamination was at least 100-fold higher than the rate of ^m5C-to-T conversion. Although this difference in reactivities suggests that the enzyme could be used to identify C5-methylated cytosines in the epigenetically important CG dinucleotides, the rate of M.SssI mediated cytosine deamination is too low to become an enzymatic alternative to the bisulfite reaction. Amino acid replacements in the presumed SAM binding pocket of M.SssI (F17S and G19D) resulted in greatly reduced methyltransferase activity. The G19D variant showed cytosine deaminase activity in E. coli, at physiological SAM concentrations. Interestingly, the C-to-U deaminase activity was also detectable in an E. coli ung ⁺ host proficient in uracil excision repair.     

Binding and structural studies of the complexes of type 1 ribosome inactivating protein from Momordica balsamina with cytosine,cytidine, and cytidine diphosphate

The type 1 ribosome inactivating protein from Momordica balsamina (MbRIP1) has been shown to interact with purine bases, adenine and guanine of RNA/DNA. We report here the binding and structural studies of MbRIP1 with a pyrimidine base, cytosine; cytosine containing nucleoside, cytidine; and cytosine containing nucleotide, cytidine diphosphate. All three compounds bound to MbRIP1 at the active site with dissociation constants of 10^?4 M–10^?7 M. As reported earlier, in the structure of native MbRIP1, there are 10 water molecules in the substrate binding site. Upon binding of cytosine to MbRIP1, four water molecules were dislodged from the substrate binding site while five water molecules were dislodged when cytidine bound to MbRIP1. Seven water molecules were dislocated when cytidine diphosphate bound to MbRIP1. This showed that cytidine diphosphate occupied a larger space in the substrate binding site enhancing the buried surface area thus making it a relatively better inhibitor of MbRIP1 as compared to cytosine and cytidine. The key residues involved in the recognition of cytosine, cytidine and cytidine diphosphate were Ile71, Glu85, Tyr111 and Arg163. The orientation of cytosine in the cleft is different from that of adenine or guanine indicating a notable difference in the modes of binding of purine and pyrimidine bases. Since adenine containing nucleosides/nucleotides are suitable substrates, the cytosine containing nucleosides/nucleotides may act as inhibitors.     

Role of DNA minor groove interactions in substrate recognition by the M.SinI and M.EcoRII DNA (cytosine-5) methyltransferases

The SinI and EcoRII DNA methyltransferases recognize sequences (GG^A/_TCC and CC^A/_TGG, respectively), which are characterized by an ^A/_T ambiguity. Recognition of the A·T and T·A base pair was studied by in vitro methyltransferase assays using oligonucleotide substrates containing a hypoxanthine·C base pair in the central position of the recognition sequence. Both enzymes methylated the substituted oligonucleotide with an efficiency that was comparable to methylation of the canonical substrate. These observations indicate that M.SinI and M.EcoRII discriminate between their canonical recognition site and the site containing a G·C or a C·G base pair in the center of the recognition sequence (GG^G/_CCC and CC^G/_CGG, respectively) by interaction(s) in the DNA minor groove. M.SinI mutants displaying a decreased capacity to discriminate between the GG^A/_TCC and GG^G/_CCC sequences were isolated by random mutagenesis and selection for the relaxed specificity phenotype. These mutations led to amino acid substitutions outside the variable region, previously thought to be the sole determinant of sequence specificity. These observations indicate that ^A/_T versus ^G/_C discrimination is mediated by interactions between the large domain of the methyltransferase and the minor groove surface of the DNA.     

Nucleotide sequences at the sites of action of the deoxyribonucleic acid modification enzyme of bacteriophage P1

Labelled oligonucleotides have been fractionated from DNAase digests of phage λ DNA that had been methylated with the phage P1 modification enzyme and S-[methyl-¹⁴C]adenosyl-l-methionine. The longest sequences established are the tetranucleotides pG-ǎ?-T-C4 and p?-T-C-T, which, together with the other sequences determined, particularly pA-G-?, show that the modification enzyme, M.EcoP1, methylates adenine residues within defined sequences and suggest that the oligonucleotide sequence recognized by this enzyme is the hexanucleotide pA-G-A-T-C-T. The duplex formed by base-pairing this hexanucleotide with its complementary sequence resembles the recognition sequence for several restriction enzymes in being bisected by an axis of 2-fold rotational symmetry.     

Structure–function correlation for the EcoRV restriction enzyme: from non-specific binding to specific DNA cleavage

The EcoRV restriction endonuclease cleaves DNA at its recognition sequence at least a million times faster than at any other DNA sequence. The only cofactor it requires for activity is Mg²⁺: but in binding to DNA in the absence of Mg²⁺, the EcoRV enzyme shows no specificity for its recognition site. Instead, the reason why EcoRV cuts one DNA sequence faster than any other is that the rate of cleavage is controlled by the binding of Mg²⁺ to EcoRV-DNA complexes: the complex at the recognition site has a high affinity for Mg²⁺, while the complexes at other DNA sequences have low affinities for Mg²⁺. The structures of the EcoRV endonuclease, and of its complexes with either 8pecific or non-specific DNA, have been solved by X-ray crystallography. In the specific complex, the protein interacts with the bases in the recognition sequence and the DNA takes up a highly distorted structure. In the non-specific complex with an unrelated DNA sequence, there are virtually no interactions with the bases and the DNA retains a B-like structure. Since the free energy changes for the formation of specific and non-specific complexes are the same, the energy from the specific interactions balances that required for the distortion of the DNA. The distortion inserts the phosphate at the scissile bond into the active site of the enzyme, where it forms part of the binding site for Mg²⁺. Without this distortion, the EcoRV–DNA complex would be unable to bind Mg²⁺ and thus unable to cleave DNA. The specificity of the EcoRV restriction enzyme is therefore governed, not by DNA binding as such, but by its ability to organize the structure of the DNA to which it is bound.     

A spectroscopic method to determine the activity of the restriction endonuclease EcoRV that involves a single reaction

A one-step protocol is presented to determine the activity of EcoRV as a model of restriction enzymes. The protocol involved a molecular beacon as DNA substrate, with the target sequence recognized by EcoRV in the stem. EcoRV cleaved the stem forming two fragments, one of which contained the fluorophore and quencher, initially bound by 3 bp. This shorter fragment rapidly dissociated at 37 °C, causing an increase of fluorescence intensity that was used to gauge the reaction kinetics. The reaction can be described using the Michaelis–Menten mechanism, and the kinetic parameters obtained were compared with literature values involving other protocols.     

Changing the recognition specificity of a DNA-methyltransferase by in vitro evolution

The gene coding for the SinI DNA-methyltransferase, a modification enzyme able to recognize and methylate the internal cytosine of the GG^A/_TCC sequence, was subjected to in vitro mutagenesis, DNA-shuffling and a strong selection for relaxed GGNCC recognition specificity. As a result of this in vitro evolution experiment, a mutant gene with the required phenotype was selected. The mutant SinI methyltransferase carried five amino acid substitutions. None of these was found in the ‘variable region’ that were thought to be responsible for sequence specificity. Three were located near the N-terminal end, preceding the first conserved structural motif of the enzyme; two were found between conserved motifs VI and VII. A clone engineered to carry out only the latter two replacements (L214S and Y229H) displays relaxed recognition specificity similar to that of the parental mutant, whereas the clone carrying only the N-terminal replacements showed a much weaker change in recognition specificity. The enzyme with two internal mutations was purified and characterized. Its catalytic activity (k_cat/K_m) was ~5-fold lower towards GG^A/_TCC and 20-fold higher towards GG^G/_CCC than that of the wild-type enzyme.     

Tuning the substrate selectivity of meta-cleavage product hydrolase by domain swapping

meta-Cleavage product (MCP) hydrolases can catalyze relatively low reactive carbon–carbon bond hydrolysis of products, which are derived from the meta-cleavage of catechols. The strict substrate selectivity of MCP hydrolases attracts an interest to understand the determinants of substrate specificity. Compared with conventional site-directed mutagenesis, domain swapping is an effective strategy to explore substrate specificity due to the large-scale reorganization of three-dimensional structure. In the present study, the hybrid MCP hydrolases BphD_LidA and MfphA_LidD were constructed by exchanging the lid domain of two parental enzymes MfphA and BphD. The residues Gly130/Ala196 (MfphA) and Gly136/Ala211 (BphD) were selected as crossover points according to structural disruption score analysis and molecular dynamics simulations. It was shown that the hybrid enzymes exhibited similar substrate selectivity with the parent enzyme providing the lid domain. Docking studies suggested that the lid domain may play a key role in determining substrate specificity by reshaping the active pocket and modulating the orientation of the substrate.     

Characterization of the adenine nucleoside specific phosphorylase of Bacillus cereus

Adenosine phosphorylase, a purine nucleoside phosphorylase endowed with high specificity for adenine nucleosides, was purified 117-fold from vegetative forms of Bacillus cereus. The purification procedure included ammonium sulphate fractionation, pH 4 treatment, ion exchange chromatography on DEAE-Sephacel, gel filtration on Sephacryl S-300 HR and affinity chromatography on N⁶-adenosyl agarose. The enzyme shows a good stability to both temperature and pH. It appears to be a homohexamer of 164 ± 5 kDa. Kinetic characterization confirmed the specificity of this phosphorylase for 6-aminopurine nucleosides. Adenosine was the preferred substrate for nucleoside phosphorolysis (k_cat/K_m 2.1 × 10⁶ s^− 1 M^− 1), followed by 2′-deoxyadenosine (k_cat/K_m 4.2 × 10⁵ s^− 1 M^− 1). Apparently, the low specificity of adenosine phosphorylase towards 6-oxopurine nucleosides is due to a slow catalytic rate rather than to poor substrate binding.     

Understanding nicotinamide dinucleotide cofactor and substrate specificity in class I flavoprotein disulfide oxidoreductases: crystallographic analysis of a glutathione amide reductase

Glutathione reductase (GR) plays a vital role in maintaining the antioxidant levels of the cytoplasm by catalyzing the reduction of glutathione disulfide to reduced glutathione, thereby using NADPH and flavin adenine dinucleotide as cofactors. Chromatiaceae have evolved an unusual homolog that prefers both a modified substrate (glutathione amide disulfide [GASSAG]) and a different cofactor (NADH). Herein, we present the crystal structure of the Chromatium gracile glutathione amide reductase (GAR) both alone and in complex with NAD⁺. An altered charge distribution in the GASSAG binding pocket explains the difference in substrate specificity. The NADH binding pocket of GAR differs from that of wild-type GR as well as that of a low active GR that was engineered to mimic NADH binding. Based on the GAR structure, we propose two attractive rationales for producing an efficient GR enzyme with NADH specificity.     

Binding and structural studies of the complexes of type 1 ribosome inactivating protein from Momordica balsamina with uracil and uridine

Ribosome inactivating protein (RIP) catalyzes the cleavage of glycosidic bond formed between adenine and ribose sugar of ribosomal RNA to inactivate ribosomes. Previous structural studies have shown that RNA bases, adenine, guanine, and cytosine tend to bind to RIP in the substrate binding site. However, the mode of binding of uracil with RIP was not yet known. Here, we report crystal structures of two complexes of type 1 RIP from Momordica balsamina (MbRIP1) with base, uracil and nucleoside, uridine. The binding studies of MbRIP1 with uracil and uridine as estimated using fluorescence spectroscopy showed that the equilibrium dissociation constants (K_D) were 1.2 × 10⁻⁶ M and 1.4 × 10⁻⁷ M respectively. The corresponding values obtained using surface plasmon resonance (SPR) were found to be 1.4 × 10⁻⁶ M and 1.1 × 10⁻⁷ M, respectively. Structures of the complexes of MbRIP1 with uracil (Structure-1) and uridine (Structure-2) were determined at 1.70 and 1.98 Å resolutions respectively. Structure-1 showed that uracil bound to MbRIP1 at the substrate binding site but its mode of binding was significantly different from those of adenine, guanine and cytosine. However, the mode of binding of uridine was found to be similar to those of cytidine. As a result of binding of uracil to MbRIP1 at the substrate binding site, three water molecules were expelled while eight water molecules were expelled when uridine bound to MbRIP1.     

Kinetic mechanism and fidelity of nick sealing by Escherichia coli NAD+-dependent DNA ligase (LigA)

Escherichia coli DNA ligase (EcoLigA) repairs 3′-OH/5′-PO₄ nicks in duplex DNA via reaction of LigA with NAD⁺ to form a covalent LigA-(lysyl-Nζ)–AMP intermediate (step 1); transfer of AMP to the nick 5′-PO₄ to form an AppDNA intermediate (step 2); and attack of the nick 3′-OH on AppDNA to form a 3′-5′ phosphodiester (step 3). A distinctive feature of EcoLigA is its stimulation by ammonium ion. Here we used rapid mix-quench methods to analyze the kinetic mechanism of single-turnover nick sealing by EcoLigA–AMP. For substrates with correctly base-paired 3′-OH/5′-PO₄ nicks, k_step2 was fast (6.8–27 s⁻¹) and similar to k_step3 (8.3–42 s⁻¹). Absent ammonium, k_step2 and k_step3 were 48-fold and 16-fold slower, respectively. EcoLigA was exquisitely sensitive to 3′-OH base mispairs and 3′ N:abasic lesions, which elicited 1000- to >20000-fold decrements in k_step2. The exception was the non-canonical 3′ A:oxoG configuration, which EcoLigA accepted as correctly paired for rapid sealing. These results underscore: (i) how EcoLigA requires proper positioning of the nick 3′ nucleoside for catalysis of 5′ adenylylation; and (ii) EcoLigA''s potential to embed mutations during the repair of oxidative damage. EcoLigA was relatively tolerant of 5′-phosphate base mispairs and 5′ N:abasic lesions.     

In vitro synthesis of spermidine in the higher plant, Vinca rosea

Cell-free extracts of $\text{Vinca rosea}$ seedlings exhibited enzyme activities for the following reactions: S-adenosyl-L-methionine (SAM) decarboxylation, spermidine synthesis from decarboxylated SAM and putrescine, and 5′-methylthioadenosine hydrolysis to 5-S-methyl-5-thio-D-ribose and adenine. SAM decarboxylation was stimulated by putrescine and inhibited by semicarbazide. The 15-fold purified ribohydrolase possessed a K_m of 1. 03 × 10^?5 M and a high specificity for 5′-methylthioadenosine.     

Dynamics of RNA modification by a multi-site-specific tRNA methyltransferase

In most organisms, the widely conserved 1-methyl-adenosine58 (m¹A₅₈) tRNA modification is catalyzed by an S-adenosyl-L-methionine (SAM)-dependent, site-specific enzyme TrmI. In archaea, TrmI also methylates the adjacent adenine 57, m¹A₅₇ being an obligatory intermediate of 1-methyl-inosine57 formation. To study this multi-site specificity, we used three oligoribonucleotide substrates of Pyrococcus abyssi TrmI (_PabTrmI) containing a fluorescent 2-aminopurine (2-AP) at the two target positions and followed the RNA binding kinetics and methylation reactions by stopped-flow and mass spectrometry. _PabTrmI did not modify 2-AP but methylated the adjacent target adenine. 2-AP seriously impaired the methylation of A₅₇ but not A₅₈, confirming that _PabTrmI methylates efficiently the first adenine of the A₅₇A₅₈A₅₉ sequence. _PabTrmI binding provoked a rapid increase of fluorescence, attributed to base unstacking in the environment of 2-AP. Then, a slow decrease was observed only with 2-AP at position 57 and SAM, suggesting that m¹A₅₈ formation triggers RNA release. A model of the protein–tRNA complex shows both target adenines in proximity of SAM and emphasizes no major tRNA conformational change except base flipping during the reaction. The solvent accessibility of the SAM pocket is not affected by the tRNA, thereby enabling S-adenosyl-L-homocysteine to be replaced by SAM without prior release of monomethylated tRNA.     

Engineered extrahelical base destabilization enhances sequence discrimination of DNA methyltransferase M.HhaI

Improved sequence specificity of the DNA cytosine methyltransferase HhaI was achieved by disrupting interactions at a hydrophobic interface between the active site of the enzyme and a highly conserved flexible loop. Transient fluorescence experiments show that mutations disrupting this interface destabilize the positioning of the extrahelical, "flipped" cytosine base within the active site. The ternary crystal structure of the F124A M.HhaI bound to cognate DNA and the cofactor analogue S-adenosyl-l-homocysteine shows an increase in cavity volume between the flexible loop and the core of the enzyme. This cavity disrupts the interface between the loop and the active site, thereby destabilizing the extrahelical target base. The favored partitioning of the base-flipped enzyme-DNA complex back to the base-stacked intermediate results in the mutant enzyme discriminating better than the wild-type enzyme against non-cognate sites. Building upon the concepts of kinetic proofreading and our understanding of M.HhaI, we describe how a 16-fold specificity enhancement achieved with a double mutation at the loop/active site interface is acquired through destabilization of intermediates prior to methyltransfer rather than disruption of direct interactions between the enzyme and the substrate for M.HhaI.     

Purification and partial characterization of NAD aminohydrolase from Aspergillus oryzae NRRL447

Aspergillus oryzae aminohydrolase free acid phosphodiesterase catalyzes nicotinamide adenine dinucleotide to deamino-NAD and ammonia. The enzyme was purified to homogeneity by a combination of acetone precipitation, anion exchange chromatography and gel filtration chromatography. The enzyme was purified 230.5 fold. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the purified enzyme showed a single protein band of MW 94 kDa. The enzyme displayed maximum activity at pH 5 and 40 °C with NAD as substrate. The enzyme activity appeared to be stable up to 40 °C. The enzyme activity was enhanced slightly by addition of Na⁺ and K⁺, whereas inhibited strongly by addition of Ag⁺, Mn²⁺, Hg²⁺ and Cu²⁺ to the reaction mixtures. The enzyme hydrolyzes several substrates, suggesting a probable non-specific nature. The enzyme catalyzes the hydrolytic cleavage of amino group of NAD, adenosine, AMP, CMP, GMP, adenosine, cytidine and cytosine to the corresponding nucleotides, nucleosides or bases and ammonia. The substrate concentration–activity relationship is the hyperbolic type and the apparent K_m and K_cat for the tested substrates were calculated.     

Interaction of the DNA bases and their mononucleotides with pyridine-2-carbaldehyde thiosemicarbazonecopper(II) complexes. Structure of the cytosine derivative

Experimental studies of the binding interactions of [CuL(NO₃)] and [{CuL′(NO₃)}₂] (HL = pyridine-2-carbaldehyde thiosemicarbazone, and HL′ = pyridine-2-carbaldehyde 4N-methylthiosemicarbazone) with adenine, guanine, cytosine, thymine and their mononucleotides (dNMP), 2-deoxyadenosine-5′-monophosphate, (dAMP), 2′-deoxyguanosine-5′-monophosphate, (dGMP), 2′-deoxycytidine-5′-monophpsphate (dCMP), and thymidine-5′-monophosphate (dTMP) have been carried out in aqueous solution at pH 6.0, I = 0.1 M (NaClO₄) and T = 25 °C. The complexation constants of these compounds, calculated by Hildebrand-Benesi plots for the dye binding, D, ([CuL] or [CuL′]) to the nucleobases or nucleotides (P), have shown two linear stretches in adenine, guanine, dAMP and dGMP. The data were analyzed in terms of formation of 1:1 DP and 1:2 DP₂ complexes with increasing purine base or nucleotide content. For cytosine and dCMP only 1:1 complexes have been observed, whereas for thymine and dTMP such complex structures were not observed. The [CuL(Hcyt)](ClO₄) cytosine derivative has been isolated and characterized. The crystal structure consists of perchlorate ions and [CuL(Hcyt)]⁺ monomers attached by hydrogen bond, chelate π−ring and anion-π interactions. The Cu²⁺ ions bind to the NNS chelating moiety of the thiosemicarbazone ligand and the cytosine N13 site (N3, most common notation) yielding a square-planar geometry. A pseudocoordination to the cytosine O12 site (=O2) can also be considered.     

AC-motif: a DNA motif containing adenine and cytosine repeat plays a role in gene regulation

I-motif or C4 is a four-stranded DNA structure with a protonated cytosine:cytosine base pair (C+:C) found in cytosine-rich sequences. We have found that oligodeoxynucleotides containing adenine and cytosine repeats form a stable secondary structure at a physiological pH with magnesium ion, which is similar to i-motif structure, and have named this structure ‘adenine:cytosine-motif (AC-motif)’. AC-motif contains C⁺:C base pairs intercalated with putative A⁺:C base pairs between protonated adenine and cytosine. By investigation of the AC-motif present in the CDKL3 promoter (AC-motif_CDKL3), one of AC-motifs found in the genome, we confirmed that AC-motif_CDKL3 has a key role in regulating CDKL3 gene expression in response to magnesium. This is further supported by confirming that genome-edited mutant cell lines, lacking the AC-motif formation, lost this regulation effect. Our results verify that adenine-cytosine repeats commonly present in the genome can form a stable non-canonical secondary structure with a non-Watson–Crick base pair and have regulatory roles in cells, which expand non-canonical DNA repertoires.