Chemical biology and medicinal chemistry of RNA methyltransferases.

RNA methyltransferases (MTases) are ubiquitous enzymes whose hitherto low profile in medicinal chemistry, contrasts with the surging interest in RNA methylation, the arguably most important aspect of the new field of epitranscriptomics. As MTases become validated as drug targets in all major fields of biomedicine, the development of small molecule compounds as tools and inhibitors is picking up considerable momentum, in academia as well as in biotech. Here we discuss the development of small molecules for two related aspects of chemical biology. Firstly, derivates of the ubiquitous cofactor S-adenosyl-l-methionine (SAM) are being developed as bioconjugation tools for targeted transfer of functional groups and labels to increasingly visible targets. Secondly, SAM-derived compounds are being investigated for their ability to act as inhibitors of RNA MTases. Drug development is moving from derivatives of cosubstrates towards higher generation compounds that may address allosteric sites in addition to the catalytic centre. Progress in assay development and screening techniques from medicinal chemistry have led to recent breakthroughs, e.g. in addressing human enzymes targeted for their role in cancer. Spurred by the current pandemic, new inhibitors against coronaviral MTases have emerged at a spectacular rate, including a repurposed drug which is now in clinical trial.

Fluorinated S-Adenosylmethionine as a Reagent for Enzyme-Catalyzed Fluoromethylation.

Strategic replacement of protons with fluorine atoms or functional groups with fluorine-containing fragments has proven a powerful strategy to optimize the activity of therapeutic compounds. For this reason, the synthetic chemistry of organofluorides has been the subject of intense development and innovation for many years. By comparison, the literature on fluorine biocatalysis still makes for a slim chapter. Herein we introduce S-adenosylmethionine (SAM) dependent methyltransferases as a new tool for the production of fluorinated compounds. We demonstrate the ability of halide methyltransferases to form fluorinated SAM (S-adenosyl-S-(fluoromethyl)-L-homocysteine) from S-adenosylhomocysteine and fluoromethyliodide. Fluorinated SAM (F-SAM) is too unstable for isolation, but is accepted as a substrate by C-, N- and O-specific methyltransferases for enzyme-catalyzed fluoromethylation of small molecules.

Structural snapshots of CmoB in various states during wobble uridine modification of tRNA.

CmoB utilizes carboxy-S-adenosyl-l-methionine (CxSAM) to carry out unusual carboxymethyl transfer to form 5-carboxymethoxyuridine (cmo5U) of several tRNA species in Gram-negative bacteria. In this report, we present three X-ray crystal structures of CmoB from Vibrio vulnificus representing different states in the course of the reaction pathway; i.e., apo-, substrate-bound, and product-bound forms. Especially, the crystal structure of apo-CmoB unveils a novel open state of the enzyme, capturing unprecedented conformational dynamics around the substrate-binding site. The apo-structure demonstrates that the open conformation favors the release of CxSAM thus representing an inactive form. Our crystal structures of CmoB complexed with CxSAM and S-adenosyl-l-homocysteine (SAH) and combined binding assay results support the proposed mechanism underlying the cofactor selectivity, where CmoB preferentially senses negative charge around amino acid residues Lys-91, Tyr-200, and Arg-315.

Synthesis of adenine dinucleosides SAM analogs as specific inhibitors of SARS-CoV nsp14 RNA cap guanine-N7-methyltransferase.

The spreading of new viruses is known to provoke global human health threat. The current COVID-19 pandemic caused by the recently emerged coronavirus SARS-CoV-2 is one significant and unfortunate example of what the world will have to face in the future with emerging viruses in absence of appropriate treatment. The discovery of potent and specific antiviral inhibitors and/or vaccines to fight these massive outbreaks is an urgent research priority. Enzymes involved in the capping pathway of viruses and more specifically RNA N7- or 2'O-methyltransferases (MTases) are now admitted as potential targets for antiviral chemotherapy. We designed bisubstrate inhibitors by mimicking the transition state of the 2'-O-methylation of the cap RNA in order to block viral 2'-O MTases. This work resulted in the synthesis of 16 adenine dinucleosides with both adenosines connected by various nitrogen-containing linkers. Unexpectedly, all the bisubstrate compounds were barely active against 2'-O MTases of several flaviviruses or SARS-CoV but surprisingly, seven of them showed efficient and specific inhibition against SARS-CoV N7-MTase (nsp14) in the micromolar to submicromolar range. The most active nsp14 inhibitor identified is as potent as but particularly more specific than the broad-spectrum MTase inhibitor, sinefungin. Molecular docking suggests that the inhibitor binds to a pocket formed by the S-adenosyl methionine (SAM) and cap RNA binding sites, conserved among SARS-CoV nsp14. These dinucleoside SAM analogs will serve as starting points for the development of next inhibitors for SARS-CoV-2 nsp14 N7-MTase.

Fluorescent SAM analogues for methyltransferase based DNA labeling.

In this work, the preparation of new S-adenosyl-l-methionine (SAM) analogues for sequence specific DNA labeling is evaluated. These non-natural analogues, comprising cysteine rather than the natural homolog, were obtained in near quantitative conversions from readily available starting materials without relying on using an excess amount of labor intensive molecules. The synthetic strategy was used to generate fluorescent cofactors, with colours spanning the whole visible spectrum, and their applicability in methyltransferase based optical mapping is shown.

Nucleoside-modified AdoMet analogues for differential methyltransferase targeting.

Methyltransferases (MTases) modify a wide range of biomolecules using S-adenosyl-l-methionine (AdoMet) as the cosubstrate. Synthetic AdoMet analogues are powerful tools to site-specifically introduce a variety of functional groups and exhibit potential to be converted only by distinct MTases. Extending the size of the substituent at the sulfur/selenium atom provides selectivity among MTases but is insufficient to discriminate between promiscuous MTases. We present a panel of AdoMet analogues differing in the nucleoside moiety (NM-AdoMets). These NM-AdoMets were efficiently produced by a previously uncharacterized methionine adenosyltransferase (MAT) from methionine and ATP analogues, such as ITP and N6-propargyl-ATP. The N6-modification changed the relative activity of three representative MTases up to 13-fold resulting in discrimination of substrates for the methyl transfer and could also be combined with transfer of allyl and propargyl groups.

Extracellular Spermine Activates DNA Methyltransferase 3A and 3B.

We first demonstrated that long-term increased polyamine (spermine, spermidine, putrescine) intake elevated blood spermine levels in mice and humans, and lifelong consumption of polyamine-rich chow inhibited aging-associated increase in aberrant DNA methylation, inhibited aging-associated pathological changes, and extend lifespan of mouse. Because gene methylation status is closely associated with aging-associated conditions and polyamine metabolism is closely associated with regulation of gene methylation, we investigated the effects of extracellular spermine supplementation on substrate concentrations and enzyme activities involved in gene methylation. Jurkat cells and human mammary epithelial cells were cultured with spermine and/or D,L-alpha-difluoromethylornithine (DFMO), an inhibitor of ornithine decarboxylase. Spermine supplementation inhibited enzymatic activities of adenosylmethionine decarboxylase in both cells. The ratio of decarboxylated S-adenosylmethionine to S-adenosyl-L-methionine increased by DFMO and decreased by spermine. In Jurkat cells cultured with DFMO, the protein levels of DNA methyltransferases (DNMTs) 1, 3A and 3B were not changed, however the activity of the three enzymes markedly decreased. The protein levels of these enzymes were not changed by addition of spermine, DNMT 3A and especially 3B were activated. We show that changes in polyamine metabolism dramatically affect substrate concentrations and activities of enzymes involved in gene methylation.

Nucleoside analogs in the study of the epitranscriptome.

Over 150 unique RNA modifications are now known including several nonstandard nucleotides present in the body of messenger RNAs. These modifications can alter a transcript's function and are collectively referred to as the epitrancriptome. Chemically modified nucleoside analogs are poised to play an important role in the study of these epitranscriptomic marks. Introduced chemical features on nucleic acid strands provide unique structures or reactivity that can be used for downstream detection or quantification. Three methods are used in the field to synthesize RNA containing chemically modified nucleoside analogs. Nucleoside analogs can be introduced by metabolic labeling, via polymerases with modified nucleotide triphosphates or via phosphoramidite-based chemical synthesis. In this review, these methods for incorporation of nucleoside analogs will be discussed with specific recently published examples pertaining to the study of the epitranscriptome.

Stuffed Methyltransferase Catalyzes the Penultimate Step of Pyochelin Biosynthesis.

Nonribosomal peptide synthetases use tailoring domains to incorporate chemical diversity into the final natural product. A structurally unique set of tailoring domains are found to be stuffed within adenylation domains and have only recently begun to be characterized. PchF is the NRPS termination module in pyochelin biosynthesis and includes a stuffed methyltransferase domain responsible for S-adenosylmethionine (AdoMet)-dependent N-methylation. Recent studies of stuffed methyltransferase domains propose a model in which methylation occurs on amino acids after adenylation and thiolation rather than after condensation to the nascent peptide chain. Herein, we characterize the adenylation and stuffed methyltransferase didomain of PchF through the synthesis and use of substrate analogues, steady-state kinetics, and onium chalcogen effects. We provide evidence that methylation occurs through an SN2 reaction after thiolation, condensation, cyclization, and reduction of the module substrate cysteine and is the penultimate step in pyochelin biosynthesis.

Development of Chaetocin and S-Adenosylmethionine Analogues as Tools for Studying Protein Methylation.

Physiological regulatory mechanisms of protein, RNA, and DNA functions include small chemical modifications, such as methylation, which are introduced or removed in a highly chemo-, regio-, and site-selective manner by methyltransferases and demethylases, respectively. However, mimicking or controlling these modifications by using labeling reagents and inhibitors remains challenging. In this Personal Account, we introduce our nascent interdisciplinary collaboration between chemists and biologists aimed at developing a basic strategy to analyse and control the methylation reactions regulated by protein methyltransferases (PMTs). We focus in particular on the structural development of chaetocin and S-adenosylmethionine to obtain PMT inhibitors and PMT substrate detectors.

Unveiling epidithiodiketopiperazine as a non-histone arginine methyltransferase inhibitor by chemical protein methylome analyses.

We present a chemical methylome analysis platform to evaluate the inhibitory activity of small molecules towards poorly characterized protein methyltransferases (PMTs), facsilitating to identify syn-HyPA-ETP-2 as a non-histone arginine methyltransferase inhibitor.

mTORC1-dependent AMD1 regulation sustains polyamine metabolism in prostate cancer.

Activation of the PTEN-PI3K-mTORC1 pathway consolidates metabolic programs that sustain cancer cell growth and proliferation. Here we show that mechanistic target of rapamycin complex 1 (mTORC1) regulates polyamine dynamics, a metabolic route that is essential for oncogenicity. By using integrative metabolomics in a mouse model and human biopsies of prostate cancer, we identify alterations in tumours affecting the production of decarboxylated S-adenosylmethionine (dcSAM) and polyamine synthesis. Mechanistically, this metabolic rewiring stems from mTORC1-dependent regulation of S-adenosylmethionine decarboxylase 1 (AMD1) stability. This novel molecular regulation is validated in mouse and human cancer specimens. AMD1 is upregulated in human prostate cancer with activated mTORC1. Conversely, samples from a clinical trial with the mTORC1 inhibitor everolimus exhibit a predominant decrease in AMD1 immunoreactivity that is associated with a decrease in proliferation, in line with the requirement of dcSAM production for oncogenicity. These findings provide fundamental information about the complex regulatory landscape controlled by mTORC1 to integrate and translate growth signals into an oncogenic metabolic program.

Helicobacter pylori does not use spermidine synthase to produce spermidine.

Helicobacter pylori is the primary pathogen associated to gastritis and gastric cancer. Growth of H. pylori depends on the availability of spermidine in vivo. Interestingly, the genome of H. pylori contains an incomplete set of genes for the classical pathway of spermidine biosynthesis. It is thus not clear whether some other genes remained in the pathway would have any functions in spermidine biosynthesis. Here, we study spermidine synthase, which is responsible for the final catalytic process in the classical route. Protein sequence alignment reveals that H. pylori SpeE (HpSpeE) lacks key residues for substrate binding. By using isothermal titration calorimetry, we show that purified recombinant HpSpeE does not interact with the putative substrates putrescine and decarboxylated S-adenosylmethionine, and the product spermidine. High performance liquid chromatography analysis further demonstrates that HpSpeE has no detectable in vitro enzymatic activity. Additionally, intracellular spermidine level in speE-null mutant strain is comparable to that in the wild type strain. Collectively, our results suggest that HpSpeE is functionally distinct from spermidine production. H. pylori may instead employ the alternative pathway for spermidine synthesis which is dominantly exploited by other human gut microbes.

The Structure and Function of the PRMT5:MEP50 Complex.

Protein arginine methyltransferase 5 (PRMT5) plays multiple roles in cellular processes at different stages of the cell cycle in a tissue specific manner. PRMT5 in complex with MEP50/p44/WDR77 associates with a plethora of partner proteins to symmetrically dimethylate arginine residues on target proteins in both the nucleus and the cytoplasm. Overexpression of PRMT5 has been observed in several cancers, making it an attractive drug target. The structure of the 453 kDa heterooctameric PRMT5:MEP50 complex bound to an S-adenosylmethionine analog and a substrate peptide provides valuable insights into this intriguing target.

Modifying the 5'-Cap for Click Reactions of Eukaryotic mRNA and To Tune Translation Efficiency in Living Cells.

The 5'-cap is a hallmark of eukaryotic mRNAs and plays fundamental roles in RNA metabolism, ranging from quality control to export and translation. Modifying the 5'-cap may thus enable modulation of the underlying processes and investigation or tuning of several biological functions. A straightforward approach is presented for the efficient production of a range of N7-modified caps based on the highly promiscuous methyltransferase Ecm1. We show that these, as well as N(2) -modified 5'-caps, can be used to tune translation of the respective mRNAs both in vitro and in cells. Appropriate modifications allow subsequent bioorthogonal chemistry, as demonstrated by intracellular live-cell labeling of a target mRNA. The efficient and versatile N7 manipulation of the mRNA cap makes mRNAs amenable to both modulation of their biological function and intracellular labeling, and represents a valuable addition to the chemical biology toolbox.

AdoMet analog synthesis and utilization: current state of the art.

S-Adenosyl-l-methionine (AdoMet) is an essential enzyme cosubstrate in fundamental biology with an expanding range of biocatalytic and therapeutic applications. In recent years, technologies enabling the synthesis and utilization of novel functional AdoMet surrogates have rapidly advanced. Developments highlighted within this brief review include improved syntheses of AdoMet analogs, unique S-adenosyl-l-methionine isosteres with enhanced stability, and corresponding applications in epigenetics, proteomics and natural product/small molecule diversification ('alkylrandomization').

Chemoenzymatic synthesis and utilization of a SAM analog with an isomorphic nucleobase.

SalL, an enzyme that catalyzes the synthesis of SAM from l-methionine and 5'-chloro-5'-deoxyoadenosine, is shown to accept 5'-chloro-5'-deoxythienoadenosine as a substrate and facilitate the synthesis of a synthetic SAM analog with an unnatural nucleobase. This synthetic cofactor is demonstrated to replace SAM in the DNA methylation reaction with M.TaqI.

One-pot modification of 5'-capped RNA based on methionine analogs.

This paper outlines chemically and enzymatically synthesized S-adenosylmethionine (AdoMet) analogs and their use in the site-specific modification of RNA by methyltransferases, enabling the facile attachment of clickable moieties to the nucleic acid. We then focus on methodological aspects of setting up a methyltransferase-based enzymatic cascade reaction starting from methionine analogs. This strategy is applied to the one-pot modification of the mRNA cap which is subsequently derivatized in copper-free and copper-catalyzed click reactions. We show that high transfer efficiencies to the cap are obtained using Se-propargyl-, hexenynyl- and azido-bearing methionine analogs. By switching to other methyltransferases our one-pot modification approach should be directly applicable to the regiospecific modification of other target molecules including nucleic acids, proteins and small molecules.

Kinetic stability of cystathionine beta-synthase can be modulated by structural analogs of S-adenosylmethionine: Potential approach to pharmacological chaperone therapy for homocystinuria.

Many pathogenic missense mutations in human cystathionine beta-synthase (CBS) cause misfolding of the mutant enzyme resulting in aggregation or rapid degradation of the protein. Subsequent loss of CBS function leads to CBS-deficient homocystinuria (CBSDH). CBS contains two sets of binding sites for S-adenosylmethionine (SAM) that independently regulate the enzyme activity and kinetically stabilize its regulatory domain. In the present study, we examined the hypothesis that CBS activation may be decoupled from kinetic stabilization and thus CBS regulatory domain can serve as a novel drug target for CBSDH. We determined the effect of SAM and its close structural analogs on CBS activity, their binding to and stabilization of the regulatory domain in the absence and presence of competing SAM. Binding of S-adenosylhomocysteine and sinefungin lead to stabilization of the regulatory domains without activation of CBS. Direct titrations and competition experiments support specific binding of these two SAM analogs to the stabilizing sites. Binding of these two ligands also affects the enzyme proteolysis rate supporting the role of the stabilizing sites in CBS dynamics. Our results indicate that binding of SAM to regulatory and stabilizing sites in CBS may have evolved to display an exquisite thermodynamic and structural specificity towards SAM as well as the ability to transduce the allosteric signal responsible for CBS activation. Thus, ligands may be developed to function as kinetic stabilizers or pharmacological chaperones without interfering with the physiological activation of CBS by SAM.