ATP Analog Research Articles

Affinity-Based Kinase-Catalyzed Crosslinking to Study Kinase-Substrate Pairs.

Phosphorylation of proteins by kinase enzymes is a post-translational modification involved in a myriad of biological events, including cell signaling and disease development. Identifying the interactions between a kinase and its phosphorylated substrate(s) is necessary to characterize phosphorylation-mediated cellular events and encourage development of kinase-targeting drugs. One method for substrate-kinase identification utilizes photocrosslinking γ-phosphate-modified ATP analogues to covalently link kinases to their substrates for subsequent monitoring. Because photocrosslinking ATP analogues require UV light, which could influence cell biology, we report here two ATP analogues, ATP-aryl fluorosulfate (ATP-AFS) and ATP-hexanoyl bromide (ATP-HexBr), that crosslink kinase-substrate pairs via proximity-mediated reactions without the need for UV irradiation. Both ATP-AFS and ATP-HexBr acted as cosubstrates with a variety of kinases for affinity-based crosslinking, with ATP-AFS showing more robust complexes. Importantly, ATP-AFS promoted crosslinking in lysates, which demonstrates compatibility with complex cellular mixtures for future application to kinase-substrate identification.

Abstract A036: Oncogenic mutations in BRAF and MEK weaken the ATP-stabilized inactive conformation of RAF to promote RAF dimerization and MAPK pathway activation

Abstract The RAS-RAF-MEK-ERK signaling axis is upregulated in many human cancers due to its central role in cell growth, differentiation and survival. Oncogenic transformation frequently arises from RAS, BRAF and MEK mutations that activate the pathway. In the clinic, similar transformations also recur as resistance mutations to KRAS.G12C inhibitor treatment. BRAF mutations at V600 (Class I) activate BRAF by releasing the kinase’s activation segment and rendering BRAF activity dimerization-independent. Yet, it remains unclear how a diverse set of dimerization-dependent BRAF mutations (Class II/III) activate the pathway. MEK mutations are assumed to bypass the RAF node entirely. We previously reported a 2.9-Å-resolution crystal structure of human BRAF kinase domain (BRAFKD) in complex with MEK and the ATP analog AMP-PCP, revealing interactions between BRAF and ATP that stabilize an inactive, pre-signaling monomeric conformation of BRAFKD and explain how ATP breaks RAF dimers in solution. Surprisingly, the β3-αC loop of MEK provides additional stabilizing interactions to the BRAF-bound AMP-PCP molecule. Utilizing an in vitro RAF dimerization assay, we find that MEK not only modulates RAF-RAF dimerization, it also enhances both the dimer-breaking effect ATP and the dimer-forming effect of paradoxical activator molecules, such as GDC-0879. Structural analysis reveals that all common oncogenic BRAF mutations alter key interactions with ATP that stabilize the inactive monomer conformation. We find ATP is unable to break RAF dimers containing Class I, II or III mutations, confirming these mutants counteract the inhibitory effects of ATP binding by lowering the threshold for RAF dimerization and thus pathway activation. We further find that oncogenic MEK mutants, in particular β3-αC loop deletions, favor RAF-RAF dimerization, even in the presence of ATP. Our study establishes a framework for rationalizing oncogenic BRAF mutations, and suggests that oncogenic MEK mutants can act, at least in part, by promoting RAF dimerization. This model provides a better understanding of activation mechanisms in the context of constantly evolving resistance mutations where oncogenesis continues to depend on the MAPK pathway. Citation Format: Timothy J. Wendorff, Jennifer Kung, Jawahar Sudhamsu. Oncogenic mutations in BRAF and MEK weaken the ATP-stabilized inactive conformation of RAF to promote RAF dimerization and MAPK pathway activation [abstract]. In: Proceedings of the AACR Special Conference: Targeting RAS; 2023 Mar 5-8; Philadelphia, PA. Philadelphia (PA): AACR; Mol Cancer Res 2023;21(5_Suppl):Abstract nr A036.

Bioisosteric Design Identifies Inhibitors of Mycobacterium tuberculosis DNA Gyrase ATPase Activity.

Mutations in DNA gyrase confer resistance to fluoroquinolones, second-line antibiotics for Mycobacterium tuberculosis infections. Identification of new agents that inhibit M. tuberculosis DNA gyrase ATPase activity is one strategy to overcome this. Here, bioisosteric designs using known inhibitors as templates were employed to define novel inhibitors of M. tuberculosis DNA gyrase ATPase activity. This yielded the modified compound R3-13 with improved drug-likeness compared to the template inhibitor that acted as a promising ATPase inhibitor against M. tuberculosis DNA gyrase. Utilization of compound R3-13 as a virtual screening template, supported by subsequent biological assays, identified seven further M. tuberculosis DNA gyrase ATPase inhibitors with IC50 values in the range of 0.42-3.59 μM. The most active compound 1 showed an IC50 value of 0.42 μM, 3-fold better than the comparator ATPase inhibitor novobiocin (1.27 μM). Compound 1 showed noncytotoxicity to Caco-2 cells at concentrations up to 76-fold higher than its IC50 value. Molecular dynamics simulations followed by decomposition energy calculations identified that compound 1 occupies the binding pocket utilized by the adenosine group of the ATP analogue AMPPNP in the M. tuberculosis DNA gyrase GyrB subunit. The most prominent contribution to the binding of compound 1 to M. tuberculosis GyrB subunit is made by residue Asp79, which forms two hydrogen bonds with the OH group of this compound and also participates in the binding of AMPPNP. Compound 1 represents a potential new scaffold for further exploration and optimization as a M. tuberculosis DNA gyrase ATPase inhibitor and candidate anti-tuberculosis agent.

Construction of Candida albicans Strains with ATP-Analog-Sensitive Protein Kinase A and Hog1.

Candida albicans is an opportunistic human fungal pathogen and a member of the mucosal microbiota. To survive in the host and cause disease, C. albicans utilizes several virulence traits, including the ability to respond and adapt to diverse stressors, as well as the morphogenetic switch between yeast and filamentous morphologies. While complex cellular circuitry governs these virulence attributes, the following two kinase-mediated signaling pathways play particularly critical roles in controlling these processes: the Hog1 mitogen-activated protein kinase (MAPK) cascade and the protein kinase A (PKA) pathway. Here, we describe the construction of C. albicans strains harboring substitutions in the ATP-binding pockets of Hog1 and the catalytic subunits of PKA, Tpk1, and Tpk2 to render their activities sensitive to the addition of bulky ATP analogs. Specifically, inhibition by the ATP analog 1NM-PP1 resulted in phenotypes characteristic of the corresponding homozygous deletion mutants for each kinase gene. These strains represent a toolset for the rapid and specific inhibition of PKA and Hog1 kinase activity to further understand their roles in regulating C. albicans morphogenesis and stress responses. IMPORTANCE As an opportunistic pathogen in humans, the fungus Candida albicans relies on virulence traits to cause disease. They include the ability to transition from yeast to filamentous morphologies and the ability to grow in diverse environmental stress conditions, including nutrient limitation, as well as osmotic and heat shock. Previous work identified the following two kinases that play a critical role in regulating these responses: Hog1 and PKA. Here, we generated versions of each kinase that are sensitive to inhibition by a bulky ATP analog, 1NM-PP1. In the presence of the analog, kinase activity is inhibited rapidly and specifically, facilitating the analysis of both kinases in regulating C. albicans morphogenesis and stress responses. Together, these strains represent an important toolset to further our understanding of C. albicans biology and virulence.

Despite their structural similarities, the cytosolic isoforms of human Hsp90 show different behaviour in thermal unfolding due to their conformation: An FTIR study

Heat shock proteins 90 (Hsp90) are chaperones that promote the proper folding of other proteins under high temperature stress situations. Hsp90s are highly conserved and ubiquitous proteins, and in mammalian cells, they are localized in the cytoplasm, endoplasmic reticulum, and mitochondria. Cytoplasmic Hsp90 are named Hsp90α and Hsp90β and differ mainly in their expression pattern: Hsp90α is expressed under stress conditions, while Hsp90β is a constitutive protein. Structurally, both share the same characteristics by presenting three well-conserved domains, one of which, the N-terminal domain, has a binding site for ATP to which various drugs targeting this protein, including radicicol, can bind. The protein is mainly found in dimeric form and adopts different conformations depending on the presence of ligands, co-chaperones and client proteins. In this study, some aspects of structure and thermal unfolding of cytoplasmic human Hsp90 were analysed by infrared spectroscopy. The effect on Hsp90β of binding with a non-hydrolysable ATP analogue and radicicol was also examined. The results obtained showed that despite the high similarity in secondary structure the two isoforms exhibit substantial differences in their behaviour during thermal unfolding, as Hsp90α exhibits higher thermal stability, slower denaturation process and different event sequence during unfolding. Ligand binding strongly stabilizes Hsp90β and slightly modifies the secondary structure of the protein as well. Most likely, these structural and thermostability characteristics are closely related to the conformational cycling of the chaperone and its propensity to exist in monomer or dimer form.

Crystal structure of the motor domain of centromere-associated protein E in complex with a non-hydrolysable ATP analogue.

Centromere-associated protein E (CENP-E) is a kinesin motor protein essential for mitosis and a new target for anticancer agents with less side effects. To rationally design anticancer drug candidates based on structure, it is important to determine the three-dimensional structure of the CENP-E motor domain bound to its inhibitor. Here, we report the first crystal structure of the CENP-E motor domain in complex with a non-hydrolysable ATP analogue, adenylyl-imidodiphosphate (AMPPNP). Furthermore, the structure is compared with the ADP-bound form of the CENP-E motor domain as well as the AMPPNP-bound forms of other kinesins. This study indicates that helix α4 of CENP-E participates in the slow binding of CENP-E to microtubules. These results will contribute to the development of anticancer drugs targeting CENP-E.

The ROK kinase N-acetylglucosamine kinase uses a sequential random enzyme mechanism with successive conformational changes upon each substrate binding

N-acetyl-d-glucosamine (GlcNAc) is a major component of bacterial cell walls. Many organisms recycle GlcNAc from the cell wall or metabolize environmental GlcNAc. The first step in GlcNAc metabolism is phosphorylation to GlcNAc-6-phosphate. In bacteria, the ROK family kinase N-acetylglucosamine kinase (NagK) performs this activity. Although ROK kinases have been studied extensively, no ternary complex showing the two substrates has yet been observed. Here, we solved the structure of NagK from the human pathogen Plesiomonas shigelloides in complex with GlcNAc and the ATP analog AMP-PNP. Surprisingly, PsNagK showed distinct conformational changes associated with the binding of each substrate. Consistent with this, the enzyme showed a sequential random enzyme mechanism. This indicates that the enzyme acts as a coordinated unit responding to each interaction. Our molecular dynamics modeling of catalytic ion binding confirmed the location of the essential catalytic metal. Additionally, site-directed mutagenesis confirmed the catalytic base and that the metal-coordinating residue is essential. Together, this study provides the most comprehensive insight into the activity of a ROK kinase.

Understanding impact of δF508 and G551D CFTR mutations on CFTR/PKA-c interaction.

The CFTR anion channel is an ATP Binding Cassette protein and consists of two pore-forming transmembrane domains, two cytosolic nucleotide binding domains that bind and hydrolyze ATP to drive gating, and a cytosolic regulatory (R) domain. The catalytic subunit of protein kinase A (PKA) binds to, and phosphorylates, the R domain, causing reversible and irreversible channel activation, respectively. CFTR chloride channel mutations cause the lethal and incurable disease cystic fibrosis (CF). The most common CF mutation, ΔF508, is known to impair CFTR protein processing and channel gating, while mutation G551D disrupts ATP-dependent channel gating. In addition, ΔF508 and G551D CFTR were also shown to be defective in PKA-dependent activation. As the stimulating effect of ivacaftor, the only FDA-approved CFTR potentiator drug, depends on CFTR phosphorylation, understanding the reason for the impaired CFTR-PKA interaction in the mutants is of great significance. The reduced rate of phosphorylation of G551D or ΔF508 channels might be a consequence of impaired PKA binding to CFTR. In the presence of ATP the contributions of PKA binding vs. phosphorylation to overall channel activation are difficult to deconvolve. Therefore, we tested reversible activation by PKA of unphosphorylated and phosphorylated mutant channels gating in P-ATP, an ATP analog that supports CFTR gating but cannot be used for phosphotransfer by PKA. Using macroscopic inside-out patch clamp recordings we compared the rates and fractional amplitudes of reversible stimulation by PKA for the mutants and wild-type CFTR. Our data show that channel activation by reversible binding of PKA is preserved in the mutant CFTR channels. Additional experiments are underway to decipher the molecular mechanism for slowed activation of the mutants.

Regulation of the phage lambda viral packaging motor's grip and DNA end-clamp mechanism

Many viruses utilize ATP-powered motors to package DNA into viral capsids. Here we use single DNA manipulation with optical tweezers and rapid solution exchange to interrogate the dynamics of DNA gripping by the phage lambda motor. Binding of poorly hydrolyzed ATP analogs results in persistent gripping and when slips occasionally occur, the release velocity is very slow, indicating significant friction between the motor and DNA. ADP induces more frequent transitions between gripping and faster slipping. Independent of nucleotides, an “end clamp” mechanism arrests slipping when the end of the DNA is about to exit the capsid. These features are qualitatively similar to those exhibited by the phage T4 motor, although there are some notable differences. Specifically, there are quantitative differences in the DNA grip/release kinetics and their dependence on nucleotides and applied force. But the most striking difference is that there are frequent long pauses during DNA exit from the capsid even in the absence of nucleotides. This pausing occurs at low capsid filling and does not increase with length of DNA packaged, indicating that it is not caused by jamming/knotting of the packaged DNA, but is attributable to fluctuation of apo-state motor subunits into a DNA gripping conformation. This finding supports our previous hypothesis that pauses which are frequently observed during packaging are caused by fluctuation of motor subunits into such a conformation. Overall, compared with T4, the lambda motor exhibits stronger interactions with DNA, which may be attributable to the small terminase subunit in the lambda packaging motor complex.

Pharmacological interventions improve myosin-actin cross-bridge function in mice with advanced chronic kidney disease.

Skeletal muscle fiber force production in adult mice with late-stage chronic kidney disease (CKD) is significantly impaired, although by different myofilament and myosin-actin cross-bridge disease responses in the various fiber types. To reverse some of the CKD-induced contractile deficits, we examined the effects of the ATP analog, 2-deoxyadenosine triphosphate (dATP), to enhance cross-bridge kinetics and the troponin sensitizer, Tirasemtiv (2 µM), to increase cross-bridge formation. Single fiber force production, myosin-actin interactions and myofilament properties were measured at 25°C in fibers from soleus and extensor digitorum longus muscles of 16-week-old CKD mice (N=5) and controls (N=5). Late-stage CKD was induced by 0.2% adenine diet for 8 weeks. dATP in myosin heavy chain (MHC) I and IIA fibers with CKD increased cross-bridge kinetics, returning them to control values or faster, leading to more strongly bound cross-bridges for maximal Ca2+-activation (pCa 4.5, pH 7.0, 5 mM Phosphate) and fatiguing (pCa 4.5, pH 6.2, 30 mM Phosphate) conditions. Specific tensions in CKD were also improved 12-21% under maximal and fatiguing conditions, except in maximally Ca2+-activated MHC I fibers, but fell short of control values. Notably, other studies have found that improvements of 13-25% in knee extensor strength in CKD patients improved their physical function, suggesting changes of this magnitude are clinically meaningful. At submaximal Ca2+-activation (pCa 6.0), Tirasemtiv in MHC IIB fibers with CKD increased myofilament stiffness 520%, number of strongly bound cross-bridges 705%, and specific tension 370%, returning specific tension back to control values. This study provides evidence that cellular and molecular contractile function in CKD may be enhanced through use of dATP or Tirasemtiv, which should be tested to potentially improve physical function and overall quality of life in late-stage CKD patients.

Using 2'-deoxy-ADP to probe stability of the myosin interacting heads motif at atomic resolution.

In addition to active cycling states, myosins within the thick filament can access an ‘inactive’ conformation called the interacting heads motif (IHM) that has been associated with the energy-conserving super relaxed (SRX) state of muscle. Thus, accessing the IHM conformation is a means of thick filament-based regulation of muscle. Only a handful of cryo-EM structures of IHM myosin are available. The large size of the IHM has similarly challenged all-atom molecular simulations of the structure. Using ANTON2, we have performed explicit solvent, all-atom molecular dynamics simulations of human cardiac β-myosin in the IHM confirmation on the microsecond timescale. In recent experimental studies, the small molecule ATP analogue, 2’-deoxy-ATP (dATP), has been shown to destabilize myosin heads from the IHM into disordered, more active states. To complement these experimental studies, we simulated β-myosin in the IHM conformation in which ADP.Pi was replaced by dADP.Pi. These simulations showed that dADP reduced the stability of the IHM by reducing the number of interactions between S1 heads. They also show that the tails of dADP.Pi-bound heads adopt conformations distinct from existing atomic models obtained with cryoEM. Thus, simulations suggest that dynamics in the RLC-binding region of the tail and at the head-head interface both contribute to IHM stability. Further, they suggest that departure from the IHM state involves coordinated motions in regions of myosin separated by over 100 Å. Ongoing analysis of the degree to which altered dynamics within the nucleotide binding pocket influence the conformation of both the head interface and RLC-binding region of the tail. These novel simulations should also prompt further research into the contribution of tail dynamics into IHM stability as well as interest in mutations that influence tail dynamics.

Step-by-step binding and unwinding of RNA by a Ded1p trimer revealed by combined high-resolution tweezers and fluorescence measurements.

The DEAD-box family of RNA helicases is the largest of all known RNA helicase families, where they remodel RNA by binding and unwinding duplex RNA via an ATP-dependent mechanism. Lacking translocation capability, these helicases are known to unwind only a limited amount, <10–20 bp, locally nearby the site of binding. However, some DEAD-box RNA helicases have recently been shown to unwind efficiently upon oligomerization. The DEAD-box RNA helicase Ded1p has been observed to efficiently unwind RNA duplexes possessing a single-stranded RNA (ssRNA) tail as a trimer. The detailed mechanism of Ded1p trimer assembly and unwinding of RNA remains unknown. We have used combined high-resolution tweezers and single-molecule fluorescence spectroscopy in order to directly observe the detailed step-by-step binding and dissociation of Ded1p protomers and subsequent unwinding and rezipping of duplex RNA. The overall trimer activity previously observed in ensemble experiments was recapitulated. A complete general model of unwinding is developed whereby unwinding is initiated by binding of a single Ded1p to the duplex adjacent ssRNA tail. Subsequently, in sequence two additional Ded1p bind and unwind a 5-7 bp portion of the duplex, each resulting in the full 16 bp duplex unwinding. The reaction is highly dynamic and stochastic, with unwinding combining with frequent rezipping reversals. Rezipping reversals are suppressed when ATP hydrolysis is suppressed via use of an ATP analog. While unwinding and rezipping are easily captured by high-resolution tweezers, Ded1p binding and dissociation on ssRNA tail was measured via the protein-induced-fluorescence-enhancement (PIFE) signal from the fluorophore-labeled tail. The combined methods allowed us to fully observe the coordinated binding and unwinding of the RNA substrate by individual protomers of the Ded1p trimer.

Structural basis of SecA-mediated protein translocation

Secretory proteins are cotranslationally or posttranslationally translocated across lipid membranes via a protein-conducting channel named SecY in prokaryotes and Sec61 in eukaryotes. The vast majority of secretory proteins in bacteria are driven through the channel posttranslationally by SecA, a highly conserved ATPase. How a polypeptide chain is moved by SecA through the SecY channel is poorly understood. Here, we report electron cryomicroscopy structures of the active SecA-SecY translocon with a polypeptide substrate. The substrate is captured in different translocation states when clamped by SecA with different nucleotides. Upon binding of an ATP analog, SecA undergoes global conformational changes to push the polypeptide substrate toward the channel in a way similar to how the RecA-like helicases translocate their nucleic acid substrates. The movements of the polypeptide substrates in the SecA-SecY translocon share a similar structural basis to those in the ribosome-SecY complex during cotranslational translocation.

Energetic vs. entropic stabilization between a Remdesivir analogue and cognate ATP upon binding and insertion into the active site of SARS-CoV-2 RNA dependent RNA polymerase.

SARS-CoV-2 RNA dependent RNA polymerase (RdRp) serves as a highly promising antiviral drug target such as for a Remdesivir nucleotide analogue (RDV-TP or RTP). In this work, we mainly used alchemical all-atom simulations to characterize relative binding free energetics between the nucleotide analogue RTP and natural cognate substrate ATP upon initial binding and pre-catalytic insertion into the active site of SARS-CoV-2 RdRp. Natural non-cognate substrate dATP and mismatched GTP were also examined for computation control. We first identified significant differences in dynamical responses between nucleotide initial binding and subsequent insertion configurations to the open and closed active sites of the RdRp, respectively, though the RdRp protein conformational changes between the active site's open and closed states are subtle. Our alchemical simulations indicated that upon initial binding (active site open), RTP and ATP show similar binding free energies to the active sites while in the insertion state (active site closed), ATP is more stabilized (∼-2.4 kcal mol-1) than RTP in free energetics. Additional analyses show, however, that RTP is more stabilized in binding energetics than ATP, in both the insertion and initial binding states, with RTP more stabilized due to the electrostatic energy in the insertion state and due to vdW energy in the initial binding state. Hence, it appears that natural cognate ATP still excels at association stability with the RdRp active site due to that ATP maintains sufficient flexibilities e.g., in base pairing with the template, which exemplifies an entropic contribution to the cognate substrate stabilization. These findings highlight the importance of substrate flexibilities in addition to energetic stabilization in antiviral nucleotide analogue design.

Crystal structure of adenosine 5ʹ-phosphosulfate kinase isolated from Archaeoglobus fulgidus

The 3′-phosphoadenosine-5′-phosphosulfate (PAPS) molecule is essential during enzyme-catalyzed sulfation reactions as a sulfate donor and is an intermediate in the reduction of sulfate to sulfite in the sulfur assimilation pathway. PAPS is produced through a two-step reaction involving ATP sulfurylase and adenosine 5′-phosphosulfate (APS) kinase enzymes/domains. However, archaeal APS kinases have not yet been characterized and their mechanism of action remains unclear. Here, we first structurally characterized APS kinase from the hyperthermophilic archaeon Archaeoglobus fulgidus, (AfAPSK). We demonstrated the PAPS production activity of AfAPSK at the optimal growth temperature (83 °C). Furthermore, we determined the two crystal structures of AfAPSK: ADP complex and ATP analog adenylyl-imidodiphosphate (AMP-PNP)/Mg2+/APS complex. Structural and complementary mutational analyses revealed the catalytic and substrate recognition mechanisms of AfAPSK. This study also hints at the molecular basis behind the thermal stability of AfAPSK.

Transient-State Kinetic Analysis of the RNA Polymerase II Nucleotide Incorporation Mechanism.

Eukaryotic RNA polymerase II (Pol II) is an essential enzyme that lies at the core of eukaryotic biology. Due to its pivotal role in gene expression, Pol II has been subjected to a substantial number of investigations. We aim to further our understanding of Pol II nucleotide incorporation by utilizing transient-state kinetic techniques to examine Pol II single nucleotide addition on the millisecond time scale. We analyzed Saccharomyces cerevisiae Pol II incorporation of ATP or an ATP analog, Sp-ATP-α-S. Here we have measured the rate constants governing individual steps of the Pol II transcription cycle in the presence of ATP or Sp-ATP-α-S. These results suggest that Pol II catalyzes nucleotide incorporation by binding the next cognate nucleotide and immediately catalyzes bond formation and bond formation is either followed by a conformational change or pyrophosphate release. By comparing our previously published RNA polymerase I (Pol I) and Pol I lacking the A12 subunit (Pol I ΔA12) results that we collected under the same conditions with the identical technique, we show that Pol II and Pol I ΔA12 exhibit similar nucleotide addition mechanisms. This observation indicates that removal of the A12 subunit from Pol I results in a Pol II like enzyme. Taken together, these data further our collective understanding of Pol II's nucleotide incorporation mechanism and the evolutionary divergence of RNA polymerases across the three domains of life.

Computational Prediction of Resistance Induced Alanine-Mutation in ATP Site of Epidermal Growth Factor Receptor.

Epidermal growth factor receptor (EGFR) resistance to tyrosine kinase inhibitors can cause low survival rates in mutation-positive non-small cell lung cancer patients. It is necessary to predict new mutations in the development of more potent EGFR inhibitors since classical and rare mutations observed were known to affect the effectiveness of the therapy. Therefore, this research aimed to perform alanine mutagenesis scanning on ATP binding site residues without COSMIC data, followed by molecular dynamic simulations to determine their molecular interactions with ATP and erlotinib compared to wild-type complexes. Based on the result, eight mutations were found to cause changes in the binding energy of the ATP analogue to become more negative. These included G779A, Q791A, L792A, R841A, N842A, V843A, I853A, and D855A, which were predicted to enhance the affinity of ATP and reduce the binding ability of inhibitors with the same interaction site. Erlotinib showed more positive energy among G779A, Q791A, I853A, and D855A, due to their weaker binding energy than ATP. These four mutations could be anticipated in the development of the next inhibitor to overcome the incidence of resistance in lung cancer patients.

Stabilization of DNA fork junctions by Smc5/6 complexes revealed by single-molecule imaging.

SMC complexes play key roles in genome maintenance, where they ensure efficient genome replication and segregation. The SMC complex Smc5/6 is a crucial player in DNA replication and repair, yet many molecular features that determine its roles are unclear. Here, we use single-molecule microscopy to investigate Smc5/6's interaction with DNA. We find that Smc5/6 forms oligomers that dynamically redistribute on dsDNA by 1D diffusion and statically bind to ssDNA. Using combined force manipulation and single-molecule microscopy, we generate ssDNA-dsDNA junctions that mimic structures present in DNA repair intermediates or replication forks. We show that Smc5/6 accumulates at these junction sites, stabilizes the fork, and promotes the retention of RPA. Our observations provide a model for the complex's enrichment at sites of replication stress and DNA lesions from where it coordinates the recruitment and activation of downstream repair proteins.

Enzymatic Generation of Double-Modified AdoMet Analogues and Their Application in Cascade Reactions with Different Methyltransferases.

Methyltransferases (MTases) have become an important tool for site-specific alkylation and biomolecular labelling. In biocatalytic cascades with methionine adenosyltransferases (MATs), transfer of functional moieties has been realized starting from methionine analogues and ATP. However, the widespread use of S-adenosyl-l-methionine (AdoMet) and the abundance of MTases accepting sulfonium centre modifications limit selective modification in mixtures. AdoMet analogues with additional modifications at the nucleoside moiety bear potential for acceptance by specific MTases. Here, we explored the generation of double-modified AdoMets by an engineered Methanocaldococcus jannaschii MAT (PC-MjMAT), using 19 ATP analogues in combination with two methionine analogues. This substrate screening was extended to cascade reactions and to MTase competition assays. Our results show that MTase targeting selectivity can be improved by using bulky substituents at the N6 of adenine. The facile access to >10 new AdoMet analogues provides the groundwork for developing MAT-MTase cascades for orthogonal biomolecular labelling.

Structure-Guided Design of Halofuginone Derivatives as ATP-Aided Inhibitors Against Bacterial Prolyl-tRNA Synthetase.

Aminoacyl-tRNA synthetases (aaRSs) are promising antimicrobial targets due to their essential roles in protein translation, and expanding their inhibitory mechanisms will provide new opportunities for drug discovery. We report here that halofuginone (HF), an herb-derived medicine, moderately inhibits prolyl-tRNA synthetases (ProRSs) from various pathogenic bacteria. A cocrystal structure of Staphylococcus aureus ProRS (SaProRS) with HF and an ATP analog was determined, which guided the design of new HF analogs. Compound 3 potently inhibited SaProRS at IC50 = 0.18 μM and Kd = 30.3 nM and showed antibacterial activities with an MIC of 1-4 μg/mL in vitro. The bacterial drug resistance to 3 only developed at a rate similar to or slower than those of clinically used antibiotics in vitro. Our study indicates that the scaffold and ATP-aided inhibitory mechanism of HF could apply to bacterial ProRS and also provides a chemical validation for using bacterial ProRS as an antibacterial target.