Complex biotransformations catalyzed by radical S-adenosylmethionine enzymes

The radical S-adenosylmethionine (AdoMet) superfamily currently comprises thousands of proteins that participate in numerous biochemical processes across all kingdoms of life. These proteins share a common mechanism to generate a powerful 5'-deoxyadenosyl radical, which initiates a highly diverse array of biotransformations. Recent studies are beginning to reveal the role of radical AdoMet proteins in the catalysis of highly complex and chemically unusual transformations, e.g. the ThiC-catalyzed complex rearrangement reaction. The unique features and intriguing chemistries of these proteins thus demonstrate the remarkable versatility and sophistication of radical enzymology.     

Adenosylation reactions catalyzed by the radical S-adenosylmethionine superfamily enzymes

The radical S-adenosylmethionine (SAM) superfamily enzymes reductively cleave SAM to produce a highly reactive 5ˊ-deoxyadenosyl (dAdo) radical, which in most cases abstracts a hydrogen from the substrate and initiates highly diverse reactions. In rare cases, the dAdo radical can add to a sp² carbon to result in the production an adenosylated product. These radical SAM-dependent adenosylation reactions are present in natural product biosynthetic pathways and can be achieved by using unnatural substrate analogs containing olefin or aryl moieties. This Opinion provides a focused perspective on this emerging type of biochemistry and discusses its potential use in bioengineering and biocatalysis.     

Biosynthesis of the sactipeptide Ruminococcin C by the human microbiome: Mechanistic insights into thioether bond formation by radical SAM enzymes

Despite its major importance in human health, the metabolic potential of the human gut microbiota is still poorly understood. We have recently shown that biosynthesis of Ruminococcin C (RumC), a novel ribosomally synthesized and posttranslationally modified peptide (RiPP) produced by the commensal bacterium Ruminococcus gnavus, requires two radical SAM enzymes (RumMC1 and RumMC2) catalyzing the formation of four C_α-thioether bridges. These bridges, which are essential for RumC''s antibiotic properties against human pathogens such as Clostridium perfringens, define two hairpin domains giving this sactipeptide (sulfur-to-α-carbon thioether–containing peptide) an unusual architecture among natural products. We report here the biochemical and spectroscopic characterizations of RumMC2. EPR spectroscopy and mutagenesis data support that RumMC2 is a member of the large family of SPASM domain radical SAM enzymes characterized by the presence of three [4Fe-4S] clusters. We also demonstrate that this enzyme initiates its reaction by C_α H-atom abstraction and is able to catalyze the formation of nonnatural thioether bonds in engineered peptide substrates. Unexpectedly, our data support the formation of a ketoimine rather than an α,β-dehydro-amino acid intermediate during C_α-thioether bridge LC–MS/MS fragmentation. Finally, we explored the roles of the leader peptide and of the RiPP precursor peptide recognition element, present in myriad RiPP-modifying enzymes. Collectively, our data support a more complex role for the peptide recognition element and the core peptide for the installation of posttranslational modifications in RiPPs than previously anticipated and suggest a possible reaction intermediate for thioether bond formation.     

Structural insights into DNMT5-mediated ATP-dependent high-fidelity epigenome maintenance

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Structural insights into SAM domain‐mediated tankyrase oligomerization

Tankyrase 1 (TNKS1; a.k.a. ARTD5) and tankyrase 2 (TNKS2; a.k.a ARTD6) are highly homologous poly(ADP‐ribose) polymerases (PARPs) that function in a wide variety of cellular processes including Wnt signaling, Src signaling, Akt signaling, Glut4 vesicle translocation, telomere length regulation, and centriole and spindle pole maturation. Tankyrase proteins include a sterile alpha motif (SAM) domain that undergoes oligomerization in vitro and in vivo. However, the SAM domains of TNKS1 and TNKS2 have not been structurally characterized and the mode of oligomerization is not yet defined. Here we model the SAM domain‐mediated oligomerization of tankyrase. The structural model, supported by mutagenesis and NMR analysis, demonstrates a helical, homotypic head‐to‐tail polymer that facilitates TNKS self‐association. Furthermore, we show that TNKS1 and TNKS2 can form (TNKS1 SAM‐TNKS2 SAM) hetero‐oligomeric structures mediated by their SAM domains. Though wild‐type tankyrase proteins have very low solubility, model‐based mutations of the SAM oligomerization interface residues allowed us to obtain soluble TNKS proteins. These structural insights will be invaluable for the functional and biophysical characterization of TNKS1/2, including the role of TNKS oligomerization in protein poly(ADP‐ribosyl)ation (PARylation) and PARylation‐dependent ubiquitylation.     

Structural characterization reveals that viperin is a radical S-adenosyl-l-methionine (SAM) enzyme

Viperin is an interferon-inducible protein inhibiting many DNA and RNA viruses. It contains an N-terminal transmembrane helix, a highly conserved C-terminus and a middle region carrying a CX3CX2C motif, characteristic of radical S-adenosyl-l-methionine (SAM) enzymes. So far no structural characterization has been reported and reconstitution of the [4Fe-4S] cluster in viperin all failed. Here, by dissecting the 361-residue human viperin into 12 fragments, followed by extensive CD and NMR characterization, Viperin (45-361) was identified to be soluble and structured in buffers. Most importantly, we have successfully reconstituted the [4Fe-4S] cluster in Viperin (45-361), thus providing the first experimental evidence confirming that viperin is indeed a radical SAM enzyme. Furthermore, the C-terminus Viperin (214-361) which is insoluble in buffers but again can be solubilized in salt-free water appears to be only partially folded. Our results thus imply that the radical SAM enzyme activity may play a key role in the broad antiviral actions of viperin.     

Pyruvate formate-lyase activating enzyme: elucidation of a novel mechanism for glycyl radical formation

Pyruvate formate lyase activating enzyme is a member of a novel superfamily of enzymes that utilize S-adenosylmethionine to initiate radical catalysis. This enzyme has been isolated with several different iron-sulfur clusters, but single turnover monitored by EPR has identified the [4Fe-4S](1+) cluster as the catalytically active cluster; this cluster is believed to be oxidized to the [4Fe-4S](2+) state during turnover. The [4Fe-4S] cluster is coordinated by a three-cysteine motif common to the radical/S-adenosylmethionine superfamily, suggesting the presence of a unique iron in the cluster. The unique iron site has been confirmed by Mossbauer and ENDOR spectroscopy experiments, which also provided the first evidence for direct coordination of S-adenosylmethionine to an iron-sulfur cluster, in this case the unique iron of the [4Fe-4S] cluster. Coordination to the unique iron anchors the S-adenosylmethionine in the active site, and allows for a close association between the sulfonium of S-adenosylmethionine and the cluster as observed by ENDOR spectroscopy. The evidence to date leads to a mechanistic proposal involving inner-sphere electron transfer from the cluster to the sulfonium of S-adenosylmethionine, followed by or concomitant with C-S bond homolysis to produce a 5'-deoxyadenosyl radical; this transient radical abstracts a hydrogen atom from G734 to activate pyruvate formate lyase.     

Structural insights into translational recoding by frameshift suppressor tRNASufJ

The three-nucleotide mRNA reading frame is tightly regulated during translation to ensure accurate protein expression. Translation errors that lead to aberrant protein production can result from the uncoupled movement of the tRNA in either the 5′ or 3′ direction on mRNA. Here, we report the biochemical and structural characterization of +1 frameshift suppressor tRNA^SufJ, a tRNA known to decode four, instead of three, nucleotides. Frameshift suppressor tRNA^SufJ contains an insertion 5′ to its anticodon, expanding the anticodon loop from seven to eight nucleotides. Our results indicate that the expansion of the anticodon loop of either ASL^SufJ or tRNA^SufJ does not affect its affinity for the A site of the ribosome. Structural analyses of both ASL^SufJ and ASL^Thr bound to the Thermus thermophilus 70S ribosome demonstrate both ASLs decode in the zero frame. Although the anticodon loop residues 34–37 are superimposable with canonical seven-nucleotide ASLs, the single C31.5 insertion between nucleotides 31 and 32 in ASL^SufJ imposes a conformational change of the anticodon stem, that repositions and tilts the ASL toward the back of the A site. Further modeling analyses reveal that this tilting would cause a distortion in full-length A-site tRNA^SufJ during tRNA selection and possibly impede gripping of the anticodon stem by 16S rRNA nucleotides in the P site. Together, these data implicate tRNA distortion as a major driver of noncanonical translation events such as frameshifting.     

Structural insights into Rhino‐Deadlock complex for germline piRNA cluster specification

PIWI‐interacting RNAs (piRNAs) silence transposons in germ cells to maintain genome stability and animal fertility. Rhino, a rapidly evolving heterochromatin protein 1 (HP1) family protein, binds Deadlock in a species‐specific manner and so defines the piRNA‐producing loci in the Drosophila genome. Here, we determine the crystal structures of Rhino‐Deadlock complex in Drosophila melanogaster and simulans. In both species, one Rhino binds the N‐terminal helix–hairpin–helix motif of one Deadlock protein through a novel interface formed by the beta‐sheet in the Rhino chromoshadow domain. Disrupting the interface leads to infertility and transposon hyperactivation in flies. Our structural and functional experiments indicate that electrostatic repulsion at the interaction interface causes cross‐species incompatibility between the sibling species. By determining the molecular architecture of this piRNA‐producing machinery, we discover a novel HP1‐partner interacting mode that is crucial to piRNA biogenesis and transposon silencing. We thus explain the cross‐species incompatibility of two sibling species at the molecular level.     

Structural and functional insights into O-methyltransferase from Bacillus cereus

The specific substrates, mechanisms, and structures of the bacterial O-methyltransferases (OMTs) are not as well characterized as those of other OMTs. Recent studies have suggested that bacterial OMTs catalyze regiospecific reactions that might be used to produce novel compounds. In this study, we investigated the structural and functional features of an OMT from Bacillus cereus (BcOMT2). This enzyme catalyzes the O-methylation of flavonoids in vitro in an S-adenosylmethionine-dependent and regiospecific manner. We solved the crystal structures of the BcOMT2 apoenzyme and the BcOMT2-S-adenosylhomocysteine (SAH) co-complex at resolutions of 1.8 and 1.2 Å, respectively. These structures reveal that the overall structure of dimeric BcOMT2 is similar to that of the canonical OMT but that BcOMT2 also has a unique N-terminal helical region that is responsible for dimerization. The binding of SAH causes both local and remote conformational changes in the dimer interface that stabilize the dimerization of BcOMT2. SAH binding also causes ordering of residues Glu171 to Gly186, which are disordered in the apoenzyme structure and are known determinants of substrate specificity, and thus contributes to formation of the substrate binding pocket. Our structural analysis indicated a resemblance between the active site of BcOMT2 and that of metal-dependent OMTs. Using mutational analysis, we confirmed that BcOMT2 is a Mg²⁺-dependent OMT. These results provide structural and functional insights into the dimerization mechanism and substrate specificity of BcOMT2.     

Structural insights into the functional divergence of WhiB-like proteins in Mycobacterium tuberculosis

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Structural insights into recognition and repair of UV-DNA damage by Spore Photoproduct Lyase, a radical SAM enzyme

Bacterial spores possess an enormous resistance to ultraviolet (UV) radiation. This is largely due to a unique DNA repair enzyme, Spore Photoproduct Lyase (SP lyase) that repairs a specific UV-induced DNA lesion, the spore photoproduct (SP), through an unprecedented radical-based mechanism. Unlike DNA photolyases, SP lyase belongs to the emerging superfamily of radical S-adenosyl-l-methionine (SAM) enzymes and uses a [4Fe–4S]¹⁺ cluster and SAM to initiate the repair reaction. We report here the first crystal structure of this enigmatic enzyme in complex with its [4Fe–4S] cluster and its SAM cofactor, in the absence and presence of a DNA lesion, the dinucleoside SP. The high resolution structures provide fundamental insights into the active site, the DNA lesion recognition and binding which involve a β-hairpin structure. We show that SAM and a conserved cysteine residue are perfectly positioned in the active site for hydrogen atom abstraction from the dihydrothymine residue of the lesion and donation to the α-thyminyl radical moiety, respectively. Based on structural and biochemical characterizations of mutant proteins, we substantiate the role of this cysteine in the enzymatic mechanism. Our structure reveals how SP lyase combines specific features of radical SAM and DNA repair enzymes to enable a complex radical-based repair reaction to take place.     

Structural studies of the interaction of S-adenosylmethionine with the [4Fe-4S] clusters in biotin synthase and pyruvate formate-lyase activating enzyme

The diverse reactions catalyzed by the radical-SAM superfamily of enzymes are thought to proceed via a set of common mechanistic steps, key among which is the reductive cleavage of S-adenosyl-L-methionine (SAM) by a reduced [4Fe-4S] cluster to generate an intermediate deoxyadenosyl radical. A number of spectroscopic studies have provided evidence that SAM interacts directly with the [4Fe-4S] clusters in several of the radical-SAM enzymes; however, the molecular mechanism for the reductive cleavage has yet to be elucidated. Selenium X-ray absorption spectroscopy (Se-XAS) was used previously to provide evidence for a close interaction between the Se atom of selenomethionine (a cleavage product of Se-SAM) and an Fe atom of the [4Fe-4S] cluster of lysine-2,3-aminomutase (KAM). Here, we utilize the same approach to investigate the possibility of a similar interaction in pyruvate formate-lyase activating enzyme (PFL-AE) and biotin synthase (BioB), two additional members of the radical-SAM superfamily. The results show that the latter two enzymes do not exhibit the same Fe-Se interaction as was observed in KAM, indicating that the methionine product of reductive cleavage of SAM does not occupy a well-defined site close to the cluster in PFL-AE and BioB. These results are interpreted in terms of the differences among these enzymes in their use of SAM as either a cofactor or a substrate.     

Mechanistic insights into transposon cleavage and integration by TnsB of ShCAST system

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Structural insights into the regulation of cohesion establishment by Wpl1

Correct segregation of duplicated chromosomes to daughter cells during mitosis requires the action of the cohesin complex. This tripartite ring‐shaped molecule is involved in holding replicated sister chromatids together from S phase until anaphase onset. Establishment of stable cohesion involves acetylation of the Smc3 component of cohesin during replication by the Eco1 acetyltransferase. This has been proposed to antagonise the activity of another member of the cohesin complex, Wpl1. Here, we describe the X‐ray structure of the conserved Wapl domain, and demonstrate that it binds the ATPase head of the Smc3 protein. We present data that suggest that Wpl1 may be involved in regulating the ATPase activity of cohesin, and that this may be subject to the acetylation state of Smc3. In addition, we present a structure of the Wapl domain bound to a functionally relevant segment of the Smc3 ATPase.     

Structural insights into chemokine CCL17 recognition by antibody M116

The homeostatic chemokine CCL17, also known as thymus and activation regulated chemokine (TARC), has been associated with various diseases such as asthma, idiopathic pulmonary fibrosis, atopic dermatitis and ulcerative colitis. Neutralization of CCL17 by antibody treatment ameliorates the impact of disease by blocking influx of T cells. Monoclonal antibody M116 derived from a combinatorial library shows potency in neutralizing CCL17-induced signaling. To gain insight into the structural determinants of antigen recognition, the crystal structure of M116 Fab was determined in complex with CCL17 and in the unbound form. Comparison of the structures revealed an unusual induced-fit mechanism of antigen recognition that involves cis-trans isomerization in two CDRs. The structure of the CCL17-M116 complex revealed the antibody binding epitope, which does not overlap with the putative receptor epitope, suggesting that the current model of chemokine-receptor interactions, as observed in the CXCR4-vMIP-II system, may not be universal.     

Structural insights into Rab21 GTPase activation mechanism by molecular dynamics simulations

Rab proteins belong to the family of monomeric GTPases which are involved in the cellular membrane trafficking. Rab21 protein exists in interchangeable GTP- and GDP-bound states. Rabs switch between two active and inactive conformations like other GTPases. The inactive form of Rab is bound to GDP while its active form is bounded with the GTP. Interexchange between active and inactive form is mediated by the GDP/GTP exchange factor (GEF) which catalyses the conversion from GDP-bound to GTP-bound form, thereby activating the Rab. While the GTP hydrolysis of Rabs is regulated by a GTPase-activating protein (GAP) which causes Rab inactivation. Here, we report the structural flexibility of the Rab21-GTP and Rab21-GDP complexes by docking and molecular dynamics (MD) simulations. Structural analysis of exchange mechanisms of the co-factors complexed with Rab21 reveals that Cys29, Thr33, His48, Gln78 and Lys133 are essentially important in the activation of proteins. Furthermore, a significant change in the orientation of the interacting co-factors, with slight variation in the free energy of binding was observed. Complexation of GEF with Rab21-GTP and Rab21-GDP reveal a flipping of the switchable residues. Finally, 50 ns MD simulations confirm that the GTP-bound Rab21 complex is thermodynamically more favoured than the corresponding GDP-bound complex. This study provides a detailed understanding of the structural elements involved in the conformational changes of Rab21.