Biochemical and structural characterization of benzenoid carboxyl methyltransferases involved in floral scent production in Stephanotis floribunda and Nicotiana suaveolens

Flower-specific benzenoid carboxyl methyltransferases from Stephanotis floribunda and Nicotiana suaveolens were biochemically and structurally characterized. The floral scents of both these species contain higher levels of methyl benzoate and lower levels of methyl salicylate. The S. floribunda enzyme has a 12-fold lower K(m) value for salicylic acid (SA) than for benzoic acid (BA), and results of in silico modeling of the active site of the S. floribunda enzyme, based on the crystal structure of Clarkia breweri salicylic acid methyltransferase (SAMT), are consistent with this functional observation. The enzyme was therefore designated SAMT. The internal concentration of BA in S. floribunda flowers is three orders of magnitude higher than the SA concentration, providing a rationale for the observation that these flowers synthesize and emit more methyl benzoate than methyl salicylate. The N. suaveolens enzyme has similar K(m) values for BA and SA, and the in silico modeling results are again consistent with this in vitro observation. This enzyme was therefore designated BSMT. However, the internal concentration of BA in N. suaveolens petals was also three orders of magnitude higher than the concentration of SA. Both S. floribunda SAMT and N. suaveolens BSMT are able to methylate a range of other benzenoid-related compounds and, in the case of S. floribunda SAMT, also several cinnamic acid derivatives, an observation that is consistent with the larger active site cavity of each of these two enzymes compared to the SAMT from C. breweri, as shown by the models. Broad substrate specificity may indicate recent evolution or an adaptation to changing substrate availability.     

Novel S-adenosyl-L-methionine:salicylic acid carboxyl methyltransferase,an enzyme responsible for biosynthesis of methyl salicylate and methyl benzoate,is not involved in floral scent production in snapdragon flowers

Using a functional genomic approach we have isolated and characterized a cDNA that encodes a salicylic acid carboxyl methyltransferase (SAMT) from Antirrhinum majus. The sequence of the protein encoded by SAMT has higher amino acid identity to Clarkia breweri SAMT than to snapdragon benzoic acid carboxyl methyltransferase (BAMT) (55 and 40% amino acid identity, respectively). Escherichia coli-expressed SAMT protein catalyzes the formation of the volatile ester methyl salicylate from salicylic acid with a K(m) value of 83 microM. It can also methylate benzoic acid to form methyl benzoate, but its K(m) value for benzoic acid is 1.72 mM. Snapdragon flowers do not emit methyl salicylate. The potential involvement of SAMT in production and emission of methyl benzoate in snapdragon flowers was analyzed by RNA gel blot analysis. SAMT mRNA was not detected in floral tissues by RNA blot hybridization, but low levels of SAMT gene expression were detected after real-time RT-PCR in the presence of SAMT-specific primers, indicating that this gene does not contribute significantly, if at all, in methyl benzoate production and emission in snapdragon flowers. Expression of SAMT in petal tissue was found to be induced by salicylic and jasmonic acid treatments.     

植物SABATH甲基转移酶研究进展

近年来对植物甲基转移酶（methyltransferases,MTs）的研究发现了新一类成员,并用最初发现的3个酶将其命名为SA-BATH甲基转移酶（SABATHMTs）,这3个酶分别是水杨酸羧基甲基转移酶（salicylic acid carboxyl methyltransferases,SAMT）、苯甲酸羧基甲基转移酶（benzoic acid carboxyl methyltransferases,BAMT）和可可碱合酶（theobromine synthase）。SABATHMTs能对植物激素和其他一些小分子物质进行N位或O位甲基化形成相应的甲基化产物,在植物次生代谢、发育及防御中起重要作用。本文从SABATHMTs潜在底物、进化及调控等方面综述了近年来对该家族的研究。     

Salicylic acid carboxyl methyltransferase induced in hairy root cultures of Atropa belladonna after treatment with exogeneously added salicylic acid

In Atropa belladonna hairy roots, exogeneously added salicylic acid (SA) is converted to methyl salicylate (MSA) through the reaction, which might be catalysed by S-adenosyl-L-methionine: salicylic acid carboxyl methyltransferase (SAMT). Here we cloned a cDNA for A. belladonna SAMT (AbSAMT1), which consisted of 357 aa residues. It was expressed in E. coli, and the recombinant AbSAMT1 showed SAMT activity. When A. belladonna hairy roots were exposed to a high concentration of SA, AbSAMT1 mRNA begins to be expressed 12 h after the exposure, and steady expression continued over 144 h.     

Positive selection for single amino acid change promotes substrate discrimination of a plant volatile-producing enzyme

We used a combined evolutionary and experimental approach tobetter understand enzyme functional divergence within the SABATHgene family of methyltransferases (MTs). These enzymes catalyzethe formation of a variety of secondary metabolites in plants,many of which are volatiles that contribute to floral scentand plant defense such as methyl salicylate and methyl jasmonate.A phylogenetic analysis of functionally characterized membersof this family showed that salicylic acid methyltransferase(SAMT) forms a monophyletic lineage of sequences found in severalflowering plants. Most members of this lineage preferentiallymethylate salicylic acid (SA) as compared with the structurallysimilar substrate benzoic acid (BA). To investigate if positiveselection promoted functional divergence of this lineage ofenzymes, we performed a branch-sites test. This test showedstatistically significant support (P < 0.05) for positiveselection in this lineage of MTs (d_N/d_S = 10.8). A high posteriorprobability (pp = 0.99) identified an active site methionineas the only site under positive selection in this lineage. Toinvestigate the potential catalytic effect of this positivelyselected codon, site-directed mutagenesis was used to replaceMet with the alternative amino acid (His) in a Datura wrightiifloral–expressed SAMT sequence. Heterologous expressionof wild-type and mutant D. wrightii SAMT in Escherichia colishowed that both enzymes could convert SA to methyl salicylateand BA to methyl benzoate. However, competitive feeding withequimolar amounts of SA and BA showed that the presence of Metin the active site of wild-type SAMT resulted in a >10-foldhigher amount of methyl salicylate produced relative to methylbenzoate. The Met156His-mutant exhibited little differentialpreference for the 2 substrates because nearly equal amountsof methyl salicylate and methyl benzoate were produced. Evolutionof the ability to discriminate between the 2 substrates by SAMTmay be advantageous for efficient production of methyl salicylate,which is important for pollinator attraction as well as pathogenand herbivore defense. Because BA is a likely precursor forthe biosynthesis of SA, SAMT might increase methyl salicylatelevels directly by preferential methylation and indirectly byleaving more BA to be converted into SA.     

Localization of methyl benzoate synthesis and emission in Stephanotis floribunda and Nicotiana suaveolens flowers

The emission of fragrances can qualitatively and quantitatively differ in different parts of flowers. A detailed analysis was initiated to localize the floral tissues and cells which contribute to scent synthesis in STEPHANOTIS FLORIBUNDA (Asclepiadaceae) and NICOTIANA SUAVEOLENS (Solanaceae). The emission of scent compounds in these species is primarily found in the lobes of the corollas and little/no emission can be attributed to other floral organs or tissues. The rim and centre of the petal lobes of S. FLORIBUNDA contribute equally to scent production since the amount of SAMT (salicylic acid carboxyl methyltransferase) and specific SAMT activity compensate each other in the rim region and centre region. IN SITU immunolocalizations with antibodies against the methyl benzoate and methyl salicylate-synthesizing enzyme indicate that the adaxial epidermis with few subepidermal cell layers of S. FLORIBUNDA is the site of SAMT accumulation. In N. SUAVEOLENS flowers, the petal rim emits twice as much methyl benzoate due to higher total protein concentrations in the rim versus the petal centre; and, both the adaxial and abaxial epidermis house the BSMT (salicylic acid/benzoic acid carboxyl methyltransferase).     

Biosynthesis and emission of insect-induced methyl salicylate and methyl benzoate from rice

Two benzenoid esters, methyl salicylate (MeSA) and methyl benzoate (MeBA), were detected from insect-damaged rice plants. By correlating metabolite production with gene expression analysis, five candidate genes encoding putative carboxyl methyltransferases were identified. Enzymatic assays with Escherichia coli-expressed recombinant proteins demonstrated that only one of the five candidates, OsBSMT1, has salicylic acid (SA) methyltransferase (SAMT) and benzoic acid (BA) methyltransferase (BAMT) activities for producing MeSA and MeBA, respectively. Whereas OsBSMT1 is phylogenetically relatively distant from dicot SAMTs, the three-dimensional structure of OsBSMT1, which was determined using homology-based structural modeling, is highly similar to those of characterized SAMTs. Analyses of OsBSMT1 expression in wild-type rice plants under various stress conditions indicate that the jasmonic acid (JA) signaling pathway plays a critical role in regulating the production and emission of MeSA in rice. Further analysis using transgenic rice plants overexpressing NH1, a key component of the SA signaling pathway in rice, suggests that the SA signaling pathway also plays an important role in governing OsBSMT1 expression and emission of its products, probably through a crosstalk with the JA signaling pathway. The role of the volatile products of OsBSMT1, MeSA and MeBA, in rice defense against insect herbivory is discussed.     

Structural, biochemical, and phylogenetic analyses suggest that indole-3-acetic acid methyltransferase is an evolutionarily ancient member of the SABATH family

The plant SABATH protein family encompasses a group of related small-molecule methyltransferases (MTs) that catalyze the S-adenosyl-L-methionine-dependent methylation of natural chemicals encompassing widely divergent structures. Indole-3-acetic acid (IAA) methyltransferase (IAMT) is a member of the SABATH family that modulates IAA homeostasis in plant tissues through methylation of IAA's free carboxyl group. The crystal structure of Arabidopsis (Arabidopsis thaliana) IAMT (AtIAMT1) was determined and refined to 2.75 A resolution. The overall tertiary and quaternary structures closely resemble the two-domain bilobed monomer and the dimeric arrangement, respectively, previously observed for the related salicylic acid carboxyl methyltransferase from Clarkia breweri (CbSAMT). To further our understanding of the biological function and evolution of SABATHs, especially of IAMT, we analyzed the SABATH gene family in the rice (Oryza sativa) genome. Forty-one OsSABATH genes were identified. Expression analysis showed that more than one-half of the OsSABATH genes were transcribed in one or multiple organs. The OsSABATH gene most similar to AtIAMT1 is OsSABATH4. Escherichia coli-expressed OsSABATH4 protein displayed the highest level of catalytic activity toward IAA and was therefore named OsIAMT1. OsIAMT1 exhibited kinetic properties similar to AtIAMT1 and poplar IAMT (PtIAMT1). Structural modeling of OsIAMT1 and PtIAMT1 using the experimentally determined structure of AtIAMT1 reported here as a template revealed conserved structural features of IAMTs within the active-site cavity that are divergent from functionally distinct members of the SABATH family, such as CbSAMT. Phylogenetic analysis revealed that IAMTs from Arabidopsis, rice, and poplar (Populus spp.) form a monophyletic group. Thus, structural, biochemical, and phylogenetic evidence supports the hypothesis that IAMT is an evolutionarily ancient member of the SABATH family likely to play a critical role in IAA homeostasis across a wide range of plants.     

Mechanism of isoprenylcysteine carboxyl methylation from the crystal structure of the integral membrane methyltransferase ICMT

The posttranslational modification of C-terminal CAAX motifs in proteins such as Ras, most Rho GTPases, and G protein γ subunits, plays an essential role in determining their subcellular localization and correct biological function. An integral membrane methyltransferase, isoprenylcysteine carboxyl methyltransferase (ICMT), catalyzes the final step of CAAX processing after prenylation of the cysteine residue and endoproteolysis of the -AAX motif. We have determined the crystal structure of a prokaryotic ICMT ortholog, revealing a markedly different architecture from conventional methyltransferases that utilize S-adenosyl-L-methionine (SAM) as a cofactor. ICMT comprises a core of five transmembrane α helices and a cofactor-binding pocket enclosed within a highly conserved C-terminal catalytic subdomain. A tunnel linking the reactive methyl group of SAM to the inner membrane provides access for the prenyl lipid substrate. This study explains how an integral membrane methyltransferase achieves recognition of both a hydrophilic cofactor and a lipophilic prenyl group attached to a polar protein substrate.     

Catalytic roles for carbon-oxygen hydrogen bonding in SET domain lysine methyltransferases

SET domain enzymes represent a distinct family of protein lysine methyltransferases in eukaryotes. Recent studies have yielded significant insights into the structural basis of substrate recognition and the product specificities of these enzymes. However, the mechanism by which SET domain methyltransferases catalyze the transfer of the methyl group from S-adenosyl-L-methionine to the lysine epsilon-amine has remained unresolved. To elucidate this mechanism, we have determined the structures of the plant SET domain enzyme, pea ribulose-1,5 bisphosphate carboxylase/oxygenase large subunit methyltransferase, bound to S-adenosyl-L-methionine, and its non-reactive analogs Aza-adenosyl-L-methionine and Sinefungin, and characterized the binding of these ligands to a homolog of the enzyme. The structural and biochemical data collectively reveal that S-adenosyl-L-methionine is selectively recognized through carbon-oxygen hydrogen bonds between the cofactor's methyl group and an array of structurally conserved oxygens that comprise the methyl transfer pore in the active site. Furthermore, the structure of the enzyme co-crystallized with the product epsilon-N-trimethyllysine reveals a trigonal array of carbon-oxygen interactions between the epsilon-ammonium methyl groups and the oxygens in the pore. Taken together, these results establish a central role for carbon-oxygen hydrogen bonding in aligning the cofactor's methyl group for transfer to the lysine epsilon-amine and in coordinating the methyl groups after transfer to facilitate multiple rounds of lysine methylation.     

Purification and characterization of S-adenosyl-L-methionine:benzoic acid carboxyl methyltransferase, the enzyme responsible for biosynthesis of the volatile ester methyl benzoate in flowers of Antirrhinum majus

S-Adenosyl-L-methionine:benzoic acid carboxyl methyltransferase (BAMT) catalyzes the transfer of the methyl group of S-adenosyl-L-methionine (SAM) to the carboxyl group of benzoic acid to make the volatile ester methyl benzoate, one of the most abundant scent compounds of snapdragon, Antirrhinum majus. The enzyme was purified from upper and lower petal lobes of 5- to 10-day-old snapdragon flowers using DE53 anion exchange, Phenyl-Sepharose 6FF, and Mono-Q chromatography. The purified protein has a pH optimum of 7.5 and is highly specific for benzoic acid, with no activity toward several other naturally occurring substrates such as salicylic acid, cinnamic acid, and their derivatives. The molecular mass values for native and denatured protein were 100 and 49 kDa, respectively, suggesting that the active enzyme is a homodimer. The addition of monovalent cations K+ and NH4+ stimulates BAMT activity by a factor of 2, whereas the addition of Fe2+ and Cu2+ has a strong inhibitory effect. Plant-purified BAMT has Km values of 28 microM and 1.1 mM for SAM and benzoic acid, respectively (87 microM and 1.6 mM, respectively, for plant BAMT expressed in Escherichia coli). Product inhibition studies showed competitive inhibition between SAM and S-adenosyl-L-homocysteine (SAH), with a Ki of 7 microM, and noncompetitive inhibition between benzoic acid and SAH, with a Ki of 14 microM.     

OsBISAMT1, a gene encoding S-adenosyl-L-methionine:salicylic acid carboxyl methyltransferase, is differentially expressed in rice defense responses

We isolated and identified a full-length cDNA, OsBISAMT1 [Oryza sativa L. benzothiadiazole (BTH)-induced SAMT 1], which encodes a putative S-adenosyl-L-methionine:salicylic acid carboxyl methyltransferase (SAMT) from rice. OsBISAMT1 contains an ORE of 1128 bp, which predicts to encode a 375 aa protein. The OsBISAMT1 protein sequence shows a high level of identity to known plant SAMTs and contains a conserved characteristic methyltransferase domain. OsBISAMT1 is a member of a small gene family in the rice genome. Expression of OsBISAMT1 in rice leaves was induced by treatments with benzothiadiazole and salicylic acid, which are capable of inducing rice disease resistance. OsBISAMT1 was also up-regulated in both incompatible and compatible interactions between rice and the blast fungus, Magnaporthe grsiea, but the induced expression of OsBISAMT1 was greater and more rapid in the incompatible interaction than that in the compatible one. Moreover, mechanical wounding also activated OsBISAMT1 expression. The results suggest that OsBISAMT1 may be involved in disease resistance responses as well as in wound response in rice.     

Synthetic peptide substrates for the erythrocyte protein carboxyl methyltransferase. Detection of a new site of methylation at isomerized L-aspartyl residues

Four hexapeptides of sequence L-Val-L-Tyr-L-Pro-(Asp)-Gly-L-Ala containing D- or L-aspartyl residues in normal or isopeptide linkages have been synthesized by the Merrifield solid-phase method as potential substrates of the erythrocyte protein carboxyl methyltransferase. This enzyme has been shown to catalyze the methylation of D-aspartyl residues in proteins in red blood cell membranes and cytosol. Using a new vapor-phase methanol diffusion assay, we have found that the normal hexapeptides containing either D- or L-aspartyl residues were not substrates for the human erythrocyte methyltransferase. On the other hand, the L-aspartyl isopeptide, in which the glycyl residue was linked in a peptide bond to the beta-carboxyl group of the aspartyl residue, was a substrate for the enzyme with a Km of 6.3 microM and was methylated with a maximal velocity equal to that observed when ovalbumin was used as a methyl acceptor. The enzyme catalyzed the transfer of up to 0.8 mol of methyl groups/mol of this peptide. Of the four synthetic peptides, only the L-isohexapeptide competitively inhibits the methylation of ovalbumin by the erythrocyte enzyme. This peptide also acts as a substrate for both of the purified protein carboxyl methyltransferases I and II which have been previously isolated from bovine brain (Aswad, D. W., and Deight, E. A. (1983) J. Neurochem. 40, 1718-1726). The L-isoaspartyl hexapeptide represents the first defined synthetic substrate for a eucaryotic protein carboxyl methyltransferase. These results demonstrate that these enzymes can not only catalyze the formation of methyl esters at the beta-carboxyl groups of D-aspartyl residues but can also form esters at the alpha-carboxyl groups of isomerized L-aspartyl residues. The implications of these findings for the metabolism of modified proteins are discussed.     

Structural mechanism of S-adenosyl methionine binding to catechol O-methyltransferase

Methyltransferases possess a homologous domain that requires both a divalent metal cation and S-adenosyl-L-methionine (SAM) to catalyze its reactions. The kinetics of several methyltransferases has been well characterized; however, the details regarding their structural mechanisms have remained unclear to date. Using catechol O-methyltransferase (COMT) as a model, we perform discrete molecular dynamics and computational docking simulations to elucidate the initial stages of cofactor binding. We find that COMT binds SAM via an induced-fit mechanism, where SAM adopts a different docking pose in the absence of metal and substrate in comparison to the holoenzyme. Flexible modeling of the active site side-chains is essential for observing the lowest energy state in the apoenzyme; rigid docking tools are unable to recapitulate the pose unless the appropriate side-chain conformations are given a priori. From our docking results, we hypothesize that the metal reorients SAM in a conformation suitable for donating its methyl substituent to the recipient ligand. The proposed mechanism enables a general understanding of how divalent metal cations contribute to methyltransferase function.     

Herbivore-Induced SABATH Methyltransferases of Maize That Methylate Anthranilic Acid Using S-Adenosyl-l-Methionine

Volatile methyl esters are common constituents of plant volatiles with important functions in plant defense. To study the biosynthesis of these compounds, especially methyl anthranilate and methyl salicylate, we identified a group of methyltransferases that are members of the SABATH enzyme family in maize (Zea mays). In vitro biochemical characterization after bacterial expression revealed three S-adenosyl-l-methionine-dependent methyltransferases with high specificity for anthranilic acid as a substrate. Of these three proteins, Anthranilic Acid Methyltransferase1 (AAMT1) appears to be responsible for most of the S-adenosyl-l-methionine-dependent methyltransferase activity and methyl anthranilate formation observed in maize after herbivore damage. The enzymes may also be involved in the formation of low amounts of methyl salicylate, which are emitted from herbivore-damaged maize. Homology-based structural modeling combined with site-directed mutagenesis identified two amino acid residues, designated tyrosine-246 and glutamine-167 in AAMT1, which are responsible for the high specificity of AAMTs toward anthranilic acid. These residues are conserved in each of the three main clades of the SABATH family, indicating that the carboxyl methyltransferases are functionally separated by these clades. In maize, this gene family has diversified especially toward benzenoid carboxyl methyltransferases that accept anthranilic acid and benzoic acid.Volatile compounds have important roles in the reproduction and defense of plants. Volatiles can attract pollinators and seed dispersers (Dobson and Bergström, 2000; Knudsen et al., 2006) or function as indirect defense compounds that attract natural enemies of herbivores (Dicke, 1994; Degenhardt et al., 2003; Howe and Jander, 2008). A well-studied example for the role of volatiles in plant defense is the tritrophic interaction between maize (Zea mays) plants, their lepidopteran herbivores, and parasitoid wasps of the herbivores. After damage by larvae of Spodoptera species, maize releases a complex volatile blend containing different classes of natural products (Turlings et al., 1990; Turlings and Benrey, 1998a). This volatile blend can be used as a cue by parasitic wasps to find hosts for oviposition (Turlings et al., 1990, 2005). After parasitization, lepidopteran larvae feed less and die upon emergence of the adult wasp, resulting in a considerable reduction in damage to the plant (Hoballah et al., 2002, 2004). The composition of the maize volatile blend is complex, consisting of terpenoids and products of the lipoxygenase pathway, along with three aromatic compounds: indole, methyl anthranilate, and methyl salicylate (Turlings et al., 1990; Degen et al., 2004; Köllner et al., 2004a). In the last decade, several studies have addressed the biosynthesis of terpenoids (Shen et al., 2000; Schnee et al., 2002, 2006; Köllner et al., 2004b, 2008a, 2008b) and indole (Frey et al., 2000, 2004) in maize. The formation of methyl anthranilate and methyl salicylate, however, has not been elucidated.Methyl anthranilate and methyl salicylate are carboxyl methyl esters of anthranilic acid, an intermediate of Trp biosynthesis, and the plant hormone salicylic acid, respectively. Our understanding of methyl anthranilate biosynthesis in plants is very limited. The only enzyme that has been described to be involved in methyl anthranilate synthesis is the anthraniloyl-CoA:methanol acyltransferase in Washington Concord grape (Vitis vinifera; Wang and De Luca, 2005). In contrast, the biosynthesis of methyl salicylate has been well studied in several plant species, such as Clarkia brewerii (Ross et al., 1999), Arabidopsis (Arabidopsis thaliana; Chen et al., 2003), and rice (Oryza sativa; Xu et al., 2006; Koo et al., 2007; Zhao et al., 2010). In all these species, methyl salicylate is synthesized by the action of S-adenosyl-l-methionine:salicylic acid carboxyl methyltransferase (SAMT). The apparent homology of SAMTs from different plant species suggests that methyl salicylate formation in maize, a species closely related to rice, is also catalyzed by an SAMT. SAMT enzymes are considered part of a larger family of methyltransferases called SABATH methyltransferases (D''Auria et al., 2003). The SABATH family also includes methyltransferases producing other methyl esters such as methyl benzoate, methyl jasmonate, and methyl indole-3-acetate (Seo et al., 2001; Effmert et al., 2005; Qin et al., 2005; Song et al., 2005; Zhao et al., 2007). An activity forming methyl anthranilate has not been described in the SABATH family, despite the striking structural similarity between methyl anthranilate and methyl salicylate or methyl benzoate. Two different classes of enzymes, methanol acyl transferases and methyltransferases, therefore, might be responsible for methyl anthranilate biosynthesis in maize (Fig. 1). Some of the SABATH methyltransferases have been shown previously to have methyltransferase activity in vitro using anthranilic acid as substrate (Chen et al., 2003; Zhao et al., 2010), but the biological relevance of such activity is unknown.Open in a separate windowFigure 1.The biosynthesis of methyl anthranilate from anthranilic acid can proceed over two pathways. Pathway A has been documented in grape, while pathway B is demonstrated here. AMAT, Anthraniloyl-CoA:methanol acyltransferase; SAH, S-adenosyl-l-homocysteine.In our ongoing attempt to investigate the biosynthesis and function of maize volatiles, we have studied the biosynthesis of the aromatic methyl esters, methyl salicylate and methyl anthranilate, and their regulation by herbivory. Biochemical characterization of maize benzenoid carboxyl methyltransferases of the SABATH family led to the discovery of a group of anthranilic acid methyltransferases (AAMTs). Homology-based structural modeling combined with site-directed mutagenesis identified the residues critical for the binding of the anthranilic acid substrate. Such functionally important residues are responsible for the diversification and evolution of benzenoid carboxyl methyltransferases in plants.