Multiple keys for a single lock: the unusual structural plasticity of the nucleotidyltransferase (4')/kanamycin complex

The most common mode of bacterial resistance to aminoglycoside antibiotics is the enzyme-catalysed chemical modification of the drug. Over the last two decades, significant efforts in medicinal chemistry have been focused on the design of non- inactivable antibiotics. Unfortunately, this strategy has met with limited success on account of the remarkably wide substrate specificity of aminoglycoside-modifying enzymes. To understand the mechanisms behind substrate promiscuity, we have performed a comprehensive experimental and theoretical analysis of the molecular-recognition processes that lead to antibiotic inactivation by Staphylococcus aureus nucleotidyltransferase 4'(ANT(4')), a clinically relevant protein. According to our results, the ability of this enzyme to inactivate structurally diverse polycationic molecules relies on three specific features of the catalytic region. First, the dominant role of electrostatics in aminoglycoside recognition, in combination with the significant extension of the enzyme anionic regions, confers to the protein/antibiotic complex a highly dynamic character. The motion deduced for the bound antibiotic seem to be essential for the enzyme action and probably provide a mechanism to explore alternative drug inactivation modes. Second, the nucleotide recognition is exclusively mediated by the inorganic fragment. In fact, even inorganic triphosphate can be employed as a substrate. Third, ANT(4') seems to be equipped with a duplicated basic catalyst that is able to promote drug inactivation through different reactive geometries. This particular combination of features explains the enzyme versatility and renders the design of non-inactivable derivatives a challenging task.     

Multiple Keys for a Single Lock: The Unusual Structural Plasticity of the Nucleotidyltransferase (4′)/Kanamycin Complex

The most common mode of bacterial resistance to aminoglycoside antibiotics is the enzyme‐catalysed chemical modification of the drug. Over the last two decades, significant efforts in medicinal chemistry have been focused on the design of non‐ inactivable antibiotics. Unfortunately, this strategy has met with limited success on account of the remarkably wide substrate specificity of aminoglycoside‐modifying enzymes. To understand the mechanisms behind substrate promiscuity, we have performed a comprehensive experimental and theoretical analysis of the molecular‐recognition processes that lead to antibiotic inactivation by Staphylococcus aureus nucleotidyltransferase 4′(ANT(4′)), a clinically relevant protein. According to our results, the ability of this enzyme to inactivate structurally diverse polycationic molecules relies on three specific features of the catalytic region. First, the dominant role of electrostatics in aminoglycoside recognition, in combination with the significant extension of the enzyme anionic regions, confers to the protein/antibiotic complex a highly dynamic character. The motion deduced for the bound antibiotic seem to be essential for the enzyme action and probably provide a mechanism to explore alternative drug inactivation modes. Second, the nucleotide recognition is exclusively mediated by the inorganic fragment. In fact, even inorganic triphosphate can be employed as a substrate. Third, ANT(4′) seems to be equipped with a duplicated basic catalyst that is able to promote drug inactivation through different reactive geometries. This particular combination of features explains the enzyme versatility and renders the design of non‐inactivable derivatives a challenging task.     

Active site labeling of the gentamicin resistance enzyme AAC(6')-APH(2") by the lipid kinase inhibitor wortmannin

BACKGROUND: Aminoglycoside antibiotic resistance is largely the result of the production of enzymes that covalently modify the drugs including kinases (APHs) with structural and functional similarity to protein and lipid kinases. One of the most important aminoglycoside resistance enzymes is AAC(6')-APH(2"), a bifunctional enzyme with both aminoglycoside acetyltransferase and kinase activities. Knowledge of enzyme active site structure is important in deciphering the molecular mechanism of antibiotic resistance and here we explored active site labeling techniques to study AAC(6')-APH(2") structure and function. RESULTS: AAC(6')-APH(2") was irreversibly inactivated by wortmannin, a potent phosphatidylinositol 3-kinase inhibitor, through the covalent modification of a conserved lysine in the ATP binding pocket. 5'-[p-(Fluorosulfonyl)benzoyl]adenosine, an electrophilic ATP analogue and known inactivator of other APH enzymes such as APH(3')-IIIa, did not inactivate AAC(6')-APH(2"), and reciprocally, wortmannin did not inactivate APH(3')-IIIa. CONCLUSIONS: These distinct active site label sensitivities point to important differences in aminoglycoside kinase active site structures and suggest that design of broad range, ATP binding site-directed inhibitors against APHs will be difficult. Nonetheless, given the sensitivity of APH enzymes to both protein and lipid kinase inhibitors, potent lead inhibitors of this important resistance enzyme are likely to be found among the libraries of compounds directed against other pharmacologically important kinases.     

Dissection of aminoglycoside-enzyme interactions: a calorimetric and NMR study of neomycin B binding to the aminoglycoside phosphotransferase(3')-IIIa

In this work, for the first time, we report pKa values of the amino functions in a target-bound aminoglycoside antibiotic, which permitted dissection of the thermodynamic properties of an enzyme-aminoglycoside complex. Uniformly enriched 15N-neomycin was isolated from cultures of Streptomyces fradiae and used to study its binding to the aminoglycoside phosphotransferase(3')-IIIa (APH) by 15N NMR spectroscopy. 15N NMR studies showed that binding of neomycin to APH causes upshifts of approximately 1 pKa unit for the amines N2' and N2' ' while N6' experienced a 0.3 pKa unit shift. The pKa of N6' ' remained unaltered, and resonances of N1 and N3 showed significant broadening upon binding to the enzyme. The binding-linked protonation and pH dependence of the association constant (Kb) for the enzyme-aminoglycoside complex was determined by isothermal titration calorimetry. The enthalpy of binding became more favorable (negative) with increasing pH. At high pH, binding-linked protonation was attributable mostly to the amino functions of neomycin; however, at neutral pH, functional groups of the enzyme, possibly remote from the active site, also underwent protonation/deprotonation upon formation of the binary enzyme-neomycin complex. The Kb for the enzyme-neomycin complex showed a complicated dependence on pH, indicating that multiple interactions may affect the affinity of the ligand to the enzyme and altered conditions, such as pH, may favor one or another. This work highlights the importance of determining thermodynamic parameters of aminoglycoside-target interactions under different conditions before making attributions to specific sites and their effects on these global parameters.     

A simple structural-based approach to prevent aminoglycoside inactivation by bacterial defense proteins. Conformational restriction provides effective protection against neomycin-B nucleotidylation by ANT4

Herein, we describe how the conformational differences exhibited by aminoglycosides in the binding pockets of the ribosome and those enzymes involved in bacterial resistance can be exploited in the design of new antibiotic derivatives with improved activity in resistant strains. The simple modification shown in the figure, leading to the conformationally restricted 5, provides an effective protection against aminoglycoside inactivation by Staphylococcus aureus ANT4, both in vivo and in vitro.     

Aminoglycosides modified by resistance enzymes display diminished binding to the bacterial ribosomal aminoacyl-tRNA site

Understanding the basic principles that govern RNA binding by aminoglycosides is important for the design of new generations of antibiotics that do not suffer from the known mechanisms of drug resistance. With this goal in mind, we examined the binding of kanamycin A and four derivatives (the products of enzymic turnovers of kanamycin A by aminoglycoside-modifying enzymes) to a 27 nucleotide RNA representing the bacterial ribosomal A site. Modification of kanamycin A functional groups that have been directly implicated in the maintenance of specific interactions with RNA led to a decrease in affinity for the target RNA. Overall, the products of reactions catalyzed by aminoglycoside resistance enzymes exhibit diminished binding to the A site of bacterial 16S rRNA, which correlates well with a loss of antibacterial ability in resistant organisms that harbor these enzymes.     

羰基还原酶辅酶结合域位点突变对其不对称催化性能的影响

基于同源模型的比较和分析,发现羰基还原酶SCR1辅酶结合域P124和W125位点对辅酶NADPH的结合形成了一定的空间位阻效应.通过对该位点进行小侧基氨基酸的取代突变,该酶的底物专一性和立体选择性均发生了不同程度的改变,表明该位点是酶与辅酶有效结合的关键位点,而且它与辅酶结合的空间效应进一步影响了底物结合域活性中心对不同构型的底物及其对映体产物的亲和作用.在底物专一性方面,野生型酶对2-羟基苯乙酮和2-溴苯乙酮及其衍生物等底物表现出较高的催化活性,而突变株W125A,W125G,P124A/W125A和P124G/W125G对苯乙酮及其部分衍生物和2-辛酮等底物的催化活性均有所提高.对于酶的立体选择性,部分突变株发生了转化产物对映体构型反转的现象,突变株P124A/W125A和P124G/W125G催化还原2-羟基苯乙酮和4-氯乙酰乙酸乙酯均生成了(R)-型产物.     

Hydrolysis of substrate analogues catalysed by beta-D-glucosidase from Aspergillus niger. Part II: Deoxy and deoxyhalo derivatives of cellobiose.

The hydrolysis of sixteen mainly deoxy and deoxyhalo derivatives of celloboise catalysed by beta-D-glucosidase from Aspergillus niger has been studied by means of 1H NMR spectroscopy and progress-curve enzyme kinetics in both single-substrate and competition experiments. In the non-reducing ring of cellobiose it was found that the hydroxy groups at positions 2', 3', and 4' are essential for the enzymatic hydrolysis. The primary hydroxy group on 6' in this ring is, although important for the hydrolysis, not essential. The analogues modified at positions 3' and 4' and the 6'-bromo-6'-deoxy derivative were not inhibitors, whereas the 2'-deoxy derivative inhibited the enzymatic hydrolysis of methyl beta-cellobioside to some extent. Of the analogues modified in the reducing ring, some were hydrolysed faster (e.g. the deoxy compounds) and some slower than methyl beta-cellobioside in single-substrate experiments, but all derivatives were hydrolysed at a lower rate than this reference substrate in direct competition and displayed relatively weak inhibitory effects. The results are interpreted qualitatively with respect to changes in the free binding energies of the substrates and catalytic transition states based on the Michaelis-Menten mechanism, and some mechanistic implications of these findings are discussed.     

Structure-Function Analysis of the S-Glycosylation Reaction in the Biosynthesis of Lincosamide Antibiotics

The S-glycosyltransferase LmbT, involved in the biosynthesis of lincomycin A, is the only known enzyme that catalyzes the enzymatic incorporation of rare amino acid L-ergothioneine (EGT) into secondary metabolites. Here, we show the structure and function analyses of LmbT. Our in vitro analysis of LmbT revealed that the enzyme shows promiscuous substrate specificity toward nitrogenous base moieties in the generation of unnatural nucleotide diphosphate (NDP)-D-α-D-lincosamides. Furthermore, the X-ray crystal structures of LmbT in its apo form and in complex with substrates indicated that the large conformational changes of the active site occur upon binding of the substrates, and that EGT is strictly recognized by salt-bridge and cation-π interactions with Arg260 and Trp101, respectively. The structure of LmbT in complex with its substrates, the docking model with the EGT-S-conjugated lincosamide, and the structure-based site-directed mutagenesis analysis revealed the structural details of the LmbT-catalyzed S_N2-like S-glycosylation reaction with EGT.     

Analysis of the pi-pi stacking interactions between the aminoglycoside antibiotic kinase APH(3')-IIIa and its nucleotide ligands

A key contact in the active site of an aminoglycoside phosphotransferase enzyme (APH(3')-IIIa) is a pi-pi stacking interaction between Tyr42 and the adenine ring of bound nucleotides. We investigated the prevalence of similar Tyr-adenine contacts and found that many different protein systems employ Tyr residues in the recognition of the adenine ring. The geometry of these stacking interactions suggests that electrostatics play a role in the attraction between these aromatic systems. Kinetic and calorimetric experiments on wild-type and mutant forms of APH(3')-IIIa yielded further experimental evidence of the importance of electrostatics in the adenine binding region and suggested that the stacking interaction contributes approximately 2 kcal/mol of binding energy. This type of information concerning the forces that govern nucleotide binding in APH(3')-IIIa will facilitate inhibitor design strategies that target the nucleotide binding site of APH-type enzymes.     

Exploring the use of conformationally locked aminoglycosides as a new strategy to overcome bacterial resistance

The emergence of bacterial resistance to the major classes of antibiotics has become a serious problem over recent years. For aminoglycosides, the major biochemical mechanism for bacterial resistance is the enzymatic modification of the drug. Interestingly, in several cases, the oligosaccharide conformation recognized by the ribosomic RNA and the enzymes responsible for the antibiotic inactivation is remarkably different. This observation suggests a possible structure-based chemical strategy to overcome bacterial resistance; in principle, it should be possible to design a conformationally locked oligosaccharide that still retains antibiotic activity but that is not susceptible to enzymatic inactivation. To explore the scope and limitations of this strategy, we have synthesized several aminoglycoside derivatives locked in the ribosome-bound "bioactive" conformation. The effect of the structural preorganization on RNA binding, together with its influence on the aminoglycoside inactivation by several enzymes involved in bacterial resistance, has been studied. Our results indicate that the conformational constraint has a modest effect on their interaction with ribosomal RNA. In contrast, it may display a large impact on their enzymatic inactivation. Thus, the work presented herein provides a key example of how the conformational differences exhibited by these ligands within the binding pockets of the ribosome and of those enzymes involved in bacterial resistance can, in favorable cases, be exploited for designing new antibiotic derivatives with improved activity in resistant strains.     

A bacterial acetyltransferase capable of regioselective N-acetylation of antibiotics and histones

The Salmonella enterica chromosomally encoded AAC(6')-Iy has been shown to confer broad aminoglycoside resistance in strains in which the structural gene is expressed. The three-dimensional structures reported place the enzyme in the large Gcn5-related N-acetyltransferase (GNAT) superfamily. The structure of the CoA-ribostamycin ternary complex allows us to propose a chemical mechanism for the reaction, and comparison with the Mycobacterium tuberculosis AAC(2')-CoA-ribostamycin complex allows us to define how regioselectivity of acetylation is achieved. The AAC(6')-Iy dimer is most structurally similar to the Saccharomyces cerevisiae Hpa2-encoded histone acetyltransferase. We demonstrate that AAC(6')-Iy catalyzes both acetyl-CoA-dependent self-alpha-N-acetylation and acetylation of eukaryotic histone proteins and the human histone H3 N-terminal peptide. These structural and catalytic similarities lead us to propose that chromosomally encoded bacterial acetyltransferases, including those functionally identified as aminoglycoside acetyltransferases, are the evolutionary progenitors of the eukaryotic histone acetyltransferases.     

Mechanism of aminoglycoside 3'-phosphotransferase type IIIa: His188 is not a phosphate-accepting residue

Background: The enzyme aminoglycoside 3′-phosphotransferase Type Illa (APH(3′)-Illa), confers resistance to many aminoglycoside antibiotics by regiospecific phosphorylation of their hydroxyl groups. The chemical mechanism of phosphoryl transfer is unknown. Based on sequence homology, it has been suggested that a conserved His residue, His188, could be phosphorylated by ATP, and this phospho-His would transfer the phosphate to the incoming aminoglycoside. We have used chemical modification, site-directed mutagenesis and positional isotope exchange methods to probe the mechanism of phosphoryl transfer by APH(3')-Illa.Results: Chemical modification by diethylpyrocarbonate implicated His in aminoglycoside phosphorylation by APH(3′)-Illa. We prepared His → Ala mutants of all four His residues in APH(3′)-Illa and found minimal effects of the mutations on the steady-state phosphorylation of several aminoglycosides. One of these mutants, His188Ala, was largely insoluble when compared to the wildtype enzyme. Positional isotope exchange experiments using γ-[¹⁸O]-ATP did not support a double-displacement mechanism.Conclusions: His residues are not required for aminoglycoside phosphorylation by APH(3′)-Illa. The conserved His188 is thus not a phosphate accepting residue but does seem to be important for proper enzyme folding. Positional isotope exchange experiments are consistent with direct attack of the aminoglycoside hydroxyl group on the γ-phosphate of ATP.     

Nucleotide sequence of aminoglycoside 6'-N-acetyltransferase [AAC(6')] determinant from Serratia sp. 45.

Gene for aminoglycoside 6'-N-acetyltransferase [AAC(6')] from Serratia sp. 45 was cloned into E. coli. The enzyme produced in E. coli carrying the recombinant plasmid was compared to the Serratia enzyme. Both enzymes acetylated the 6'-C position of amikacin, dibekacin, tobramycin, sisomicin, gentamicin C1a and kanamycin but effected gentamicin C1, gentamicin C2 and micronomycin minimally. No significant difference in optimal pH, isoelectric point or molecular weight was detected. The nucleotide sequence of the gene was determined. Initiating with a GTG codon for methionine, it was composed of 552 base pair coding for 184 amino acids. The molecular weight of the enzyme was about 20418. Comparison of the amino acid sequence of this AAC(6') with the amino acid sequence of aacA4 gene from Serratia marcescens (G. Tran Van Nhieu and E. Collatz, J. Bacteriol., 169, 5708(1987)) showed 98.3% homology.     

Structural aspects for the recognition of ATP by ribonucleopeptide receptors

A modular structure of ribonucleopeptide (RNP) affords a framework to construct macromolecular receptors and fluorescent sensors. We have isolated ATP-binding RNP with the minimum of nucleotides for ATP binding, in which the RNA consensus sequence is different from those reported for RNA aptamers against the ATP analogues. The three-dimensional structure of the substrate-binding complex of RNP was studied to understand the ATP-binding mechanism of RNP. A combination of NMR measurements, enzymatic and chemical mapping, and nucleotide mutation studies of the RNP-adenosine complex show that RNP interacts with the adenine ring of adenosine by forming a U:A:U triple with two invariant U nucleotides. The observed recognition mode for the adenine ring is different from those of RNA aptamers for ATP derivatives reported previously. The RNP-adenosine complex is folded into a particular structure by formation of the U:A:U triple and a Hoogsteen type A:U base pair. This recognition mechanism was successfully utilized to convert the substrate-binding specificity of RNP from ATP- to GTP-binding with a C(+):G:C triple recognition mode.     

Computer-aided active-site-directed modeling of the Herpes Simplex Virus 1 and human thymidine kinase

Summary Thymidine kinase (TK), which is induced by Herpes Simplex Virus 1 (HSV1), plays a key role in the antiviral activity of guanine derivatives such as aciclovir (ACV). In contrast, ACV shows only low affinity to the corresponding host cell enzyme. In order to define the differences in substrate binding of the two enzymes on molecular level, models for the three-dimensional (3-D) structures of the active sites of HSV1-TK and human TK were developed. The reconstruction of the active sites started from primary and secondary structure analysis of various kinases. The results were validated to homologous enzymes with known 3-D structures. The models predict that both enzymes consist of a central core -sheet structure, connected by loops and -helices very similar to the overall structure of other nucleotide binding enzymes. The phosphate binding is made up of a highly conserved glycine-rich loop at the N-terminus of the proteins and a conserved region at the C-terminus. The thymidine recognition site was found about 100 amino acids downstream from the phosphate binding loop. The differing substrate specificity of human and HSV1-TK can be explained by amino-acid substitutions in the homologous regions.To achieve a better understanding of the structure of the active site and how the thymidine kinase proteins interact with their substrates, the corresponding complexes of thymidine and dihydroxypropoxyguanine (DHPG) with HSV1 and human TK were built. For the docking of the guanine derivative, the X-ray structure of Elongation Factor Tu (EF-Tu), co-crystallized with guanosine diphosphate, was taken as reference. Fitting of thymidine into the active sites was done with respect to similar interactions found in thymidylate kinase. To complement the analysis of the 3-D structures of the two kinases and the substrate enzyme interactions, site-directed mutagenesis of the thymidine recognition site of HSV1-TK has been undertaken, changing Asp¹⁶² in the thymidine recognition site into Asn. First investigations reveal that the enzymatic activity of the mutant protein is destroyed.     

Structural Modeling of TRPA1 Ion Channel—Determination of the Binding Site for Antagonists

TRPA1 is a transmembrane cation channel, one of the most promising targets in the context of respiratory diseases. Its general structure has already been experimentally resolved, but the binding site of TRPA1 antagonists such as HC-030031, a model methylxanthine derivative, remains unknown. The present study aimed to determine the potential binding site of xanthine antagonists and to describe their binding mode, using a molecular modeling approach. This study represents the first attempt to bring together site-directed mutagenesis reports and the latest cryo-EM structure of an antagonist bound to TRPA1. Our research suggests that the core moiety of HC-030031 binds to a pocket formed by the TRP-like domain and the pre-S1, S4, S5 helices of one subunit. The structure, determined by cryo-EM, shows interactions of a core hypoxanthine moiety in the same area of the binding site, sharing the interaction of xanthine/hypoxanthine with Trp-711. Moreover, the predicted binding mode of HC-030031 assumes interaction with Asn-855, a residue demonstrated to be important for HC-030031 recognition in site-directed mutagenesis studies. Our model proved to be advantageous in a retrospective virtual screening benchmark; therefore, it will be useful in research on new TRPA1 antagonists among xanthine derivatives and their bioisosteres.     

苹果酸酶结合域定点突变对烟酰胺腺嘌呤二核苷酸类似物催化性能的影响

通过对苹果酸酶(ME)辅酶结合域L310、Q401、L404饱和位点突变库与辅酶烟酰胺腺嘌呤二核苷酸(NAD⁺)类似物库的高通量筛选,研究了苹果酸酶结合域位点对NAD⁺及其类似物(B1~B7)催化活性的影响。 结果表明,突变后酶ME-Q401H/L404T对类似物B4的k_cat/K_m是野生型酶的50倍;突变后酶ME-L310M/Q401N对类似物B4的k_cat/K_m是野生型酶的16倍,对类似物B3的k_cat/K_m是野生型酶的5倍,因此通过对结合域定点突变,NAD⁺类似物的催化活性得到提高。     

Diarylethynyl amides that recognize the parallel conformation of genomic promoter DNA G-quadruplexes

We report bis-phenylethynyl amide derivatives as a potent G-quadruplex binding small molecule scaffold. The amide derivatives were efficiently prepared in 3 steps by employing Sonogashira coupling, ester hydrolysis and a chemoselective amide coupling. Ligand-quadruplex recognition has been evaluated using a fluorescence resonance energy transfer (FRET) melting assay, surface plasmon resonance (SPR), circular dichroism (CD) and (1)H nuclear magnetic resonance (NMR) spectroscopy. While most of the G-quadruplex ligands reported so far comprise a planar, aromatic core designed to stack on the terminal tetrads of a G-quadruplex, these compounds are neither polycyclic, nor macrocyclic and have free rotation around the triple bond enabling conformational flexibility. Such molecules show very good binding affinity, excellent quadruplex:duplex selectivity and also promising discrimination between intramolecular promoter quadruplexes. Our results indicate that the recognition of the c-kit2 quadruplex by these ligands is achieved through groove binding, which favors the formation of a parallel conformation.     

间苯二甲酰腙分子钳的合成及阴离子识别研究

设计合成了3种新型间苯二甲酰腙类化合物,利用UV-Vis及¹H NMR考察了其与F^-、Cl^-、Br^-、I^-、CH₃COO^-、HSO₄^-、H₂PO4-、ClO4-阴离子的相互作用。结果表明,主体分子4a(双对硝基苯并呋喃甲醛间苯二甲酰腙)在DMSO溶液中对F-和CH₃COO-有显著识别效果,溶液颜色由黄色变为深黄色和棕红色。通过¹H NMR滴定及质子溶剂效应进一步证明,主体分子与阴离子之间是以氢键作用方式相结合。Job曲线表明,主客体间形成1：1型氢键络合物。基于实验结果,探讨了主客体间形状和大小匹配对识别能力的影响以及主客体之间的识别模式。