Structural analysis of a putative aminoglycoside N-acetyltransferase from Bacillus anthracis

For the last decade, worldwide efforts for the treatment of anthrax infection have focused on developing effective vaccines. Patients that are already infected are still treated traditionally using different types of standard antimicrobial agents. The most popular are antibiotics such as tetracyclines and fluoroquinolones. While aminoglycosides appear to be less effective antimicrobial agents than other antibiotics, synthetic aminoglycosides have been shown to act as potent inhibitors of anthrax lethal factor and may have potential application as antitoxins. Here, we present a structural analysis of the BA2930 protein, a putative aminoglycoside acetyltransferase, which may be a component of the bacterium's aminoglycoside resistance mechanism. The determined structures revealed details of a fold characteristic only for one other protein structure in the Protein Data Bank, namely, YokD from Bacillus subtilis. Both BA2930 and YokD are members of the Antibiotic_NAT superfamily (PF02522). Sequential and structural analyses showed that residues conserved throughout the Antibiotic_NAT superfamily are responsible for the binding of the cofactor acetyl coenzyme A. The interaction of BA2930 with cofactors was characterized by both crystallographic and binding studies.     

An aminoglycoside sensing riboswitch controls the expression of aminoglycoside resistance acetyltransferase and adenyltransferases

The emergence of antibiotic resistance in human pathogens is an increasing threat to public health. The fundamental mechanisms that control the high levels of expression of antibiotic resistance genes are not yet completely understood. The aminoglycosides are one of the earliest classes of antibiotics that were introduced in the 1940s. In the clinic aminoglycoside resistance is conferred most commonly through enzymatic modification of the drug although resistance through enzymatic modification of the target rRNA through methylation or the overexpression of efflux pumps is also appearing. An aminoglycoside sensing riboswitch has been identified that controls expression of the aminoglycoside resistance genes that encode the aminoglycoside acetyltransferase (AAC) and aminoglycoside nucleotidyltransferase (ANT) (adenyltransferase (AAD)) enzymes. AAC and ANT cause resistance to aminoglycoside antibiotics through modification of the drugs. Expression of the AAC and ANT resistance genes is regulated by aminoglycoside binding to the 5′ leader RNA of the aac/aad genes. The aminoglycoside sensing RNA is also associated with the integron cassette system that captures antibiotic resistance genes. Specific aminoglycoside binding to the leader RNA induces a structural transition in the leader RNA, and consequently induction of resistance protein expression. Reporter gene expression, direct measurements of drug RNA binding, chemical probing and UV cross-linking combined with mutational analysis demonstrated that the leader RNA functioned as an aminoglycoside sensing riboswitch in which drug binding to the leader RNA leads to the induction of aminoglycoside antibiotic resistance. This article is part of a Special Issue entitled: Riboswitches.     

Studying aminoglycoside modification by the acetyltransferase class of resistance-causing enzymes via microarray

Aminoglycosides are broad-spectrum antibacterials to which some bacteria have acquired resistance. The most common mode of resistance to aminoglycosides is enzymatic modification of the drug by different classes of enzymes including acetyltransferases (AACs). Thus, the modification of aminoglycosides by AAC(2′) from Mycobacterium tuberculosis and AAC(3) from Escherichia coli was studied using aminoglycoside microarrays. Results show that both enzymes modify their substrates displayed on an array surface in a manner that mimics their relative levels of modification in solution. Because aminoglycosides that are modified by resistance-causing enzymes have reduced affinities for binding their therapeutic target, the bacterial rRNA aminoacyl-tRNA site (A-site), arrays were probed for binding to a fluorescently labeled oligonucleotide mimic of the A-site after modification. A decrease in binding was observed when aminoglycosides were modified by AAC(3). In contrast, a decrease in binding of the A-site is not observed when aminoglycosides are modified by AAC(2′). Interestingly, these effects mirror the biological functions of the enzymes: the AAC(3) used in this study is known to confer aminoglycoside resistance, while the AAC(2′) is chromosomally encoded and unlikely to play a role in resistance. These studies lay a direct foundation for studying resistance to aminoglycosides and can also have more broad applications in identifying and studying non-aminoglycoside carbohydrates or proteins as substrates for acetyltransferase enzymes.     

Mechanistic characterization of the bifunctional aminoglycoside-modifying enzyme AAC(3)-Ib/AAC(6')-Ib' from Pseudomonas aeruginosa

A recently discovered bifunctional antibiotic-resistance enzyme named AAC(3)-Ib/AAC(6')-Ib', from Pseudomonas aeruginosa, catalyzes acetylation of aminoglycoside antibiotics. Since both domains are acetyltransferases, each was cloned and purified for mechanistic studies. The AAC(3)-Ib domain appears to be highly specific to fortimicin A and gentamicin as substrates, while the AAC(6')-Ib' domain exhibits a broad substrate spectrum. Initial velocity patterns indicate that both domains follow a sequential kinetic mechanism. The use of dead-end and product inhibition and solvent-isotope effect reveals that both domains catalyze their reactions by a steady-state ordered Bi-Bi kinetic mechanism, in which acetyl-CoA is the first substrate that binds to the active site, followed by binding of the aminoglycoside antibiotic. Subsequent to the transfer of the acetyl group, acetylated aminoglycoside is released prior to coenzyme A. The merger of two genes to create a bifunctional enzyme with expanded substrate profile would appear to be a recent trend in evolution of resistance to aminoglycoside antibiotics, of which four examples have been documented in the past few years.     

Kinetic mechanism of the GCN5-related chromosomal aminoglycoside acetyltransferase AAC(6')-Ii from Enterococcus faecium: evidence of dimer subunit cooperativity

The aminoglycoside 6'-N-acetyltransferase AAC(6')-Ii from Enterococcus faecium is an important microbial resistance determinant and a member of the GCN5-related N-acetyltransferase (GNAT) superfamily. We report here the further characterization of this enzyme in terms of the kinetic mechanism of acetyl transfer and identification of rate-contributing step(s) in catalysis, as well as investigations into the binding of both acetyl-CoA and aminoglycoside substrates to the AAC(6')-Ii dimer. Product and dead-end inhibition studies revealed that AAC(6')-Ii follows an ordered bi-bi ternary complex mechanism with acetyl-CoA binding first followed by antibiotic. Solvent viscosity studies demonstrated that aminoglycoside binding and product release govern the rate of acetyl transfer, as evidenced by changes in both the k(cat)/K(b) for aminoglycoside and k(cat), respectively, with increasing solvent viscosity. Solvent isotope effects were consistent with our viscosity studies that diffusion-controlled processes and not the chemical step were rate-limiting in drug modification. The patterns of partial and mixed inhibition observed during our mechanistic studies were followed up by investigating the possibility of subunit cooperativity in the AAC(6')-Ii dimer. Through the use of AAC-Trp(164) --> Ala, an active mutant which exists as a monomer in solution, the partial nature of the competitive inhibition observed in wild-type dead-end inhibition studies was alleviated. Isothermal titration calorimetry studies also indicated two nonequivalent antibiotic binding sites for the AAC(6')-Ii dimer but only one binding site for the Trp(164) --> Ala mutant. Taken together, these results demonstrate subunit cooperativity in the AAC(6')-Ii dimer, with possible relevance to other oligomeric members of the GNAT superfamily.     

ATP binding enables broad antibiotic selectivity of aminoglycoside phosphotransferase(3')-IIIa: an elastic network analysis

The bacterial enzyme aminoglycoside phosphotransferase(3′)-IIIa (APH) confers resistance against a wide range of aminoglycoside antibiotics. In this study, we use the Gaussian network model to investigate how the binding of nucleotides and antibiotics influences the dynamics and thereby the ligand binding properties of APH. Interestingly, in NMR experiments, the dynamics differ significantly in various APH complexes, although crystallographic studies indicate that no larger conformational changes occur upon ligand binding. Isothermal titration calorimetry also shows different thermodynamic contributions to ligand binding. Formation of aminoglycoside-APH complexes is enthalpically driven, while the enthalpic change upon aminoglycoside binding to the nucleotide-APH complex is much smaller. The differential effects of nucleotide binding and antibiotic binding to APH can be explained theoretically by single-residue fluctuations and correlated motions of the enzyme. The surprising destabilization of β-sheet residues upon nucleotide binding, as seen in hydrogen/deuterium exchange experiments, shows that the number of closest neighbors does not fully explain residue flexibility. Additionally, we must consider correlated motions of dynamic protein domains, which show that not only connectivity but also the overall protein architecture is important for protein dynamics.     

3-Hydroxy-3-methylglutaryl coenzyme A synthase. Evidence for an acetyl-S-enzyme intermediate and identification of a cysteinyl sulfhydryl as the site of acetylation.

Homogeneous liver 3-hydroxy-3-methylglutaryl coenzyme A synthase, which catalyzes the condensation of acetyl-CoA with acetoacetyl-CoA to form 3-hydroxy-3-methylglutaryl-CoA, also carries out: (a) a rapid transacetylation from acetyl-CoA to 31-dephospho-CoA and (b) a slow hydrolysis of acetyl-CoA to acetate and CoA. Transacetylation and hydrolysis occur at 50 and 1 percent, respectively, the rate of the synthasecatalyzed condensation reaction. It appears that an acetyl-enzyme intermediate is involved in the transacetylase and hydrolase reactions of 3-hydroxy-3-methylglutaryl-CoA synthase, as well as in the over-all condensation process. Covalent binding to the enzyme of a [14C]acetyl group contributed by [1(-14)C]acetyl-CoA is indicated by migration of the [14C]acetyl group with the dissociated synthase upon electrophoresis in dodecyl sulfate-urea and by precipitation of [14C]acetyl-enzyme with trichloroacetic acid. At 0 degrees and a saturating level of acetyl-CoA, the synthase is rapidly (less than 20 s) acetylated yielding 0.6 acetyl group/enzyme dimer. Performic acid oxidation completely deacetylates the enzyme, suggesting the site of acetylation to be a cysteinyl sulfhydryl group. Proteolytic digestion of [14C]acetyl-S-enzyme under conditions favorable for intramolecular S to N acetyl group transfer quantitatively liberates a labeled derivative with a [14C]acetyl group stable to performic acid oxidation. The labeled oxidation product is identified as N-[14C]acetylcysteic acid, thus demonstrating a cysteinyl sulfhydryl group as the original site of acetylation. The ability of the acetylated enzyme, upon addition of acetoacetyl-CoA, to form 3-hydroxy-3-methylglutaryl-CoA indicates that the acetylated cysteine residue is at the catalytic site.     

Thermodynamics of aminoglycoside binding to aminoglycoside-3'-phosphotransferase IIIa studied by isothermal titration calorimetry

The aminoglycoside-3'-phosphotransferase IIIa [APH(3')-IIIa] phosphorylates aminoglycoside antibiotics and renders them ineffective against bacteria. APH(3')-IIIa is the most promiscuous aminoglycoside phosphotransferase enzyme, and it modifies more than 10 different aminoglycoside antibiotics. A wealth of information exists about the enzyme; however, thermodynamic properties of enzyme-aminoglycoside complexes are still not known. This study describes the determination of the thermodynamic parameters of the binary enzyme-aminoglycoside and the ternary enzyme-metal-ATP-aminoglycoside complexes of structurally related aminoglycosides using isothermal titration calorimetry. Formation of the binary enzyme-aminoglycoside complexes is enthalpically driven and exhibits a strongly disfavored entropic contribution. Formation of the ternary enzyme-metal-ATP-aminoglycoside complexes yields much smaller negative DeltaH values and more favorable entropic contributions. The presence of metal-ATP generally increases the affinity of aminoglycosides to the enzyme. This is consistent with the kinetic mechanism of the enzyme in which ordered binding of substrates occurs. However, the observed DeltaH values neither correlate with kinetic parameters k(cat), K(m), and k(cat)/K(m) nor correlate with the molecular size of the substrates. Comparison of the thermodynamic properties of the complexes formed by structurally similar aminoglycosides indicated that the 2'- and the 6'-amino groups of the substrates are involved in binding to the enzyme. Thermodynamic properties of the complexes formed by aminoglycosides differing only at the 3'-hydroxyl group suggested that the absence of this group does not alter the thermodynamic parameters of the ternary APH(3')-IIIa-metal-ATP-aminoglycoside complex. Our results also indicate that protonation of ligand and protein ionizable groups is coupled to the complex formation between aminoglycosides and APH(3')-IIIa. Comparison of DeltaH values for different aminoglycoside-enzyme complexes indicates that enzyme and substrates undergo significant conformational changes in complex formation.     

Comparing aminoglycoside binding sites in bacterial ribosomal RNA and aminoglycoside modifying enzymes

Aminoglycoside antibiotics are used against severe bacterial infections. They bind to the bacterial ribosomal RNA and interfere with the translation process. However, bacteria produce aminoglycoside modifying enzymes (AME) to resist aminoglycoside actions. AMEs form a variable group and yet they specifically recognize and efficiently bind aminoglycosides, which are also diverse in terms of total net charge and the number of pseudo‐sugar rings. Here, we present the results of 25 molecular dynamics simulations of three AME representatives and aminoglycoside ribosomal RNA binding site, unliganded and complexed with an aminoglycoside, kanamycin A. A comparison of the aminoglycoside binding sites in these different receptors revealed that the enzymes efficiently mimic the nucleic acid environment of the ribosomal RNA binding cleft. Although internal dynamics of AMEs and their interaction patterns with aminoglycosides differ, the energetical analysis showed that the most favorable sites are virtually the same in the enzymes and RNA. The most copied interactions were of electrostatic nature, but stacking was also replicated in one AME:kanamycin complex. In addition, we found that some water‐mediated interactions were very stable in the simulations of the complexes. We show that our simulations reproduce well findings from NMR or X‐ray structural studies, as well as results from directed mutagenesis. The outcomes of our analyses provide new insight into aminoglycoside resistance mechanism that is related to the enzymatic modification of these drugs. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Molecular mechanism of the enterococcal aminoglycoside 6'-N-acetyltransferase': role of GNAT-conserved residues in the chemistry of antibiotic inactivation

The Gram-positive pathogen Enterococcus faecium is intrinsically resistant to aminoglycoside antibiotics due to the presence of a chromosomally encoded aminoglycoside 6'-N-acetyltransferase [AAC(6')-Ii]. This enzyme is a member of the GCN5-related N-acetyltransferase (GNAT) superfamily and is therefore structurally homologous to proteins that catalyze acetyl transfer to diverse acyl-accepting substrates. This study reports the investigation of several potential catalytic residues that are present in the AAC(6')-Ii active site and also conserved in many GNAT enzymes. Site-directed mutagenesis of Glu72, His74, Leu76, and Tyr147 with characterization of the purified site mutants gave valuable information about the roles of these amino acids in acetyl transfer chemistry. More specifically, steady-state kinetic analysis of protein activity, solvent viscosity effects, pH studies, and antibiotic resistance profiles were all used to assess the roles of Glu72 and His74 as potential active site bases, Tyr147 as a general acid, and the importance of the amide NH group of Leu76 in transition-state stabilization. Taken together, our results indicate that Glu72 is not involved in general base catalysis, but is instead critical for the proper positioning and orientation of aminoglycoside substrates in the active site. Similarly, His74 is also not acting as the active site base, with pH studies revealing that this residue must be protonated for optimal AAC(6')-Ii activity. Mutation of Tyr147 was found not to affect the chemical step of catalysis, and our results were not consistent with this residue acting as a general acid. Last, the amide NH group of Leu76 is implicated in important interactions with acetyl-CoA and transition-state stabilization. In summary, the work described here provides important information regarding the molecular mechanism of AAC(6')-Ii catalysis that allows us to contrast our findings with those of other GNAT proteins and to demonstrate that these enzymes use a variety of chemical mechanisms to accelerate acyl transfer.     

Kinetic and mutagenic characterization of the chromosomally encoded Salmonella enterica AAC(6')-Iy aminoglycoside N-acetyltransferase

The chromosomally encoded aminoglycoside N-acetyltransferase, AAC(6')-Iy, from Salmonella enterica confers resistance toward a number of aminoglycoside antibiotics. The structural gene was cloned and expressed and the purified enzyme existed in solution as a dimer of ca. 17 000 Da monomers. Acetyl-CoA was the preferred acyl donor, and most therapeutically important aminoglycosides were substrates for acetylation. Exceptions are those aminoglycosides that possess a 6'-hydroxyl substituent (e.g., lividomycin). Thus, the enzyme exhibited regioselective and exclusive acetyltransferase activity to 6'-amine-containing aminoglycosides. The enzyme exhibited Michaelis-Menten kinetics for some aminoglycoside substrates but "substrate activation" with others. Kinetic studies supported a random kinetic mechanism for the enzyme. The enzyme was inactivated by iodoacetamide in a biphasic manner, with half of the activity being lost rapidly and the other half more slowly. Tobramycin, but not acetyl-CoA, protected against inactivation. Each of the three cysteine residues (C70, C109, C145) in the wild-type enzyme were carboxamidomethylated by iodoacetamide. Cysteine 109 in AAC(6')-Iy is conserved in 12 AAC(6') enzyme sequences of the major class I subfamily. Surprisingly, mutation of this residue to alanine neither abolished activity nor altered the biphasic inactivation by iodoacetamide. The maximum velocity and V/K values for a number of aminoglycosides were elevated in this single mutant, and the kinetic behavior of substrates exhibiting linear vs nonlinear kinetics was reversed. Cysteine 70 in AAC(6')-Iy is either a cysteine or a threonine residue in all 12 AAC(6') enzymes of the major class I subfamily. The double mutant, C109A/C70A, was not inactivated by iodoacetamide. The double mutant exhibited large increases in the K(m) values for both acetyl-CoA and aminoglycoside substrates, and all aminoglycoside substrates exhibited Michaelis-Menten kinetics. Solvent kinetic isotope effects on V/K were normal for the WT enzyme and inverse for the double mutant. We discuss a chemical mechanism and the likely rate-limiting steps for both the wild-type and mutant forms of the enzyme.     

Substrate specificity of acetyl-CoA-carboxylase from the rat liver

The interaction between acetyl-CoA fragments and rat liver acetyl-CoA carboxylase was studied. It was found that the 3'-phosphate group did not interfere with the enzyme interaction since the substrate properties of acetyl-dephospho-CoA and acetyl-CoA are nearly identical. The non-nucleotide substrate analogs S-acetyl-pantethin and its 4'-phosphate) also displayed substrate properties (V = 1.5% and 15% of the V for acetyl-CoA carboxylation respectively). The nucleotide fragment of the acetyl-CoA molecule produced an appreciable effect on the thermodynamics of this substrate interaction with the enzyme. Its physiological role consists in all probability, in the activation and propes orientation of the acetyl group in the enzyme active center. The far more pronounced substrate properties of S-acetyl pantethin 4'-phosphate and the inhibitory properties of pantethin 4'-phosphate (compared to non-phosphorylated analogs) suggest the essential role of the beta-phosphate residue of ADP in the acetyl-CoA binding to the enzyme. The data obtained suggest also that the hydrophobic region responsible for the acyl radical binding, has a site which specifically recognizes the beta-mercaptoethyl residue of the CoA pantethin fragment. The pivotal role in the acetyl-CoA carboxylase interaction with the substrate is ascribed to the productive binding of the acetyl radical; the contribution of individual fragment of the CoA molecule is variable.     

Interaction of aminoglycoside antibiotics with surface Asp and Glu residues of phosphatidylinositol-specific phospholipase C

The aminoglycoside antibiotics such as neomycin, gentamicin, kanamycin and streptomycin stimulated the purified enzyme phosphatidylinositol-specific phospholipases C from Bacillus thuringiensis at pH 5.5. The involvement of net positive charge of aminoglycoside antibiotics (AA) on phosphatidylinositol-specific phospholipases C activation was probed by modifying the carboxyl group of Asp and Glu present in the enzyme by 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide (EDAC). Intrinsic Trp fluorescence of EDAC modified and unmodified PI-PLC in the presence of AA confirmed the interaction of AA with side chain carboxyl group of aspartic and glutamic acid of the enzyme. Thus, the possible interaction of aminoglycoside antibiotics with phosphatidylinositol-specific phospholipases C is predicted to be mediated through the aspartic and glutamic acid residue(s) of the protein.     

Deciphering interactions of the aminoglycoside phosphotransferase(3′)‐IIIa with its ligands

Aminoglycoside phosphotransferase(3′)‐IIIa (APH) is the enzyme with broadest substrate range among the phosphotransferases that cause resistance to aminoglycoside antibiotics. In this study, the thermodynamic characterization of interactions of APH with its ligands are done by determining dissociation constants of enzyme–substrate complexes using electron paramagnetic resonance and fluorescence spectroscopy. Metal binding studies showed that three divalent cations bind to the apo‐enzyme with low affinity. In the presence of AMPPCP, binding of the divalent cations occurs with 7‐to‐37‐fold higher affinity to three additional sites dependent on the presence and absence of different aminoglycosides. Surprisingly, when both ligands, AMPPCP and aminoglycoside, are present, the number of high affinity metal binding sites is reduced to two with a 2‐fold increase in binding affinity. The presence of divalent cations, with or without aminoglycoside present, shows only a small effect (<3‐fold) on binding affinity of the nucleotide to the enzyme. The presence of metal–nucleotide, but not nucleotide alone, increases the binding affinity of aminoglycosides to APH. Replacement of magnesium (II) with manganese (II) lowered the catalytic rates significantly while affecting the substrate selectivity of the enzyme such that the aminoglycosides with 2′‐NH₂ become better substrates (higher V_max) than those with 2′‐OH. © 2009 Wiley Periodicals, Inc. Biopolymers 91: 801–809, 2009. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

A high-throughput screening assay for the carboxyltransferase subunit of acetyl-CoA carboxylase

One consequence of the dramatic rise of antibiotic-resistant pathogenic bacteria is the need for new targets for antibiotics. Because membrane lipid biogenesis is essential for bacterial growth, enzymes of the fatty acid biosynthetic pathway offer attractive possibilities for the development of new antibiotics. Acetyl-coenzyme A carboxylase (ACC) catalyzes the first committed and regulated step in fatty acid biosynthesis in bacteria and thus is a prime target for development of antibiotics. ACC is a multifunctional enzyme composed of three separate proteins. The biotin carboxylase component catalyzes the ATP-dependent carboxylation of biotin. The biotin carboxyl carrier protein features a biotin molecule covalently attached at Lys122 of the Escherichia coli enzyme. The carboxyltransferase subunit catalyzes the transfer of a carboxyl group from biotin to acetyl-coenzyme A (acetyl-CoA) to form malonyl-CoA. The objective of this study was to develop an assay for high-throughput screening for inhibitors of the carboxyltransferase subunit. The carboxyltransferase reaction was assayed in the reverse direction in which malonyl-CoA reacts with biocytin (an analog of the biotin carboxyl carrier protein) to form acetyl-CoA and carboxybiotin. The production of acetyl-CoA was coupled to citrate synthase, which produced citrate and coenzyme A. The amount of coenzyme A formed was detected using 5,5'-dithiobis(2-nitrobenzoic acid) (Ellman's reagent). The assay has been developed for use in both 96- and 384-well microplate formats and was validated using a known bisubstrate analog inhibitor of carboxyltransferase. The spectrophotometric readout in the visible absorbance range used in this assay does not generate the number of false negatives associated with frequently used NAD/NADH assay systems that rely on detection of NADH using UV absorbance.     

Crystal structures of antibiotic-bound complexes of aminoglycoside 2'-phosphotransferase IVa highlight the diversity in substrate binding modes among aminoglycoside kinases

Aminoglycoside 2'-phosphotransferase IVa [APH(2')-IVa] is a member of a family of bacterial enzymes responsible for medically relevant resistance to antibiotics. APH(2')-IVa confers high-level resistance against several clinically used aminoglycoside antibiotics in various pathogenic Enterococcus species by phosphorylating the drug, thereby preventing it from binding to its ribosomal target and producing a bactericidal effect. We describe here three crystal structures of APH(2')-IVa, one in its apo form and two in complex with a bound antibiotic, tobramycin and kanamycin A. The apo structure was refined to a resolution of 2.05 ?, and the APH(2')-IVa structures with tobramycin and kanamycin A bound were refined to resolutions of 1.80 and 2.15 ?, respectively. Comparison among the structures provides insight concerning the substrate selectivity of this enzyme. In particular, conformational changes upon substrate binding, involving rotational shifts of two distinct segments of the enzyme, are observed. These substrate-induced shifts may also rationalize the altered substrate preference of APH(2')-IVa in comparison to those of other members of the APH(2') subfamily, which are structurally closely related. Finally, analysis of the interactions between the enzyme and aminoglycoside reveals a distinct binding mode as compared to the intended ribosomal target. The differences in the pattern of interactions can be utilized as a structural basis for the development of improved aminoglycosides that are not susceptible to these resistance factors.     

Characterization of a key aminoglycoside phosphotransferase in gentamicin biosynthesis

Gentamicin is an aminoglycoside antibiotic obtained from cultures of Micromonospora as the important anti-infective agents. Gentamicin which lacks 3′-hydroxyl group can avoid the attack from the modification enzymes of antibiotic-resistant bacteria in clinic. Consequently, C-3′ dehydroxylation is the key step in gentamicins biosynthesis. We suppose that there are some enzymes responsible for converting intermediate JI-20A to 3′,4′-bisdehydroxylated final product gentamicin C_1a, while phosphorylation of 3′-OH is possibly the first step for C-3′ dehydroxylation. The gentamicin biosynthetic gene gntI, encoding an aminoglycoside phosphotransferase, was cloned from Micromonospora echinospora ATCC15835 and overexpressed in Escherichia coli. The resulting phosphotransferase was purified, and the kinetic parameters for Kanamycin A, Kanamycin B, Neomycin B and Amikacin were determined. Elucidation of NMR data of phosphorylated kanamycin B has unambiguously demonstrated a regiospecific phosphorylation of 3′-hydroxyl of the 6-aminohexose ring. The results described here partly confirm that the 3′-dehydroxylation step is preceded by a 3′ phosphorylation step. It is predicted that GntI belongs to a new aminoglycoside phosphotransferase group involved with aminoglycoside antibiotics biosynthesis pathway.     

Phosphoryl transfer by aminoglycoside 3'-phosphotransferases and manifestation of antibiotic resistance

Transfer of the gamma-phosphoryl group from ATP to aminoglycoside antibiotics by aminoglycoside 3'-phosphotransferases is one of the most important reactions for manifestation of bacterial resistance to this class of antibiotics. This review article surveys the latest structural and mechanistic findings with these enzymes.     

The COOH terminus of aminoglycoside phosphotransferase (3')-IIIa is critical for antibiotic recognition and resistance.

The aminoglycoside phosphotransferases (APHs) are widely distributed among pathogenic bacteria and are employed to covalently modify, and thereby detoxify, the clinically relevant aminoglycoside antibiotics. The crystal structure for one of these aminoglycoside kinases, APH(3')-IIIa, has been determined in complex with ADP and analysis of the electrostatic surface potential indicates that there is a large anionic depression present adjacent to the terminal phosphate group of the nucleotide. This region also includes a conserved COOH-terminal alpha-helix that contains the COOH-terminal residue Phe(264). We report here mutagenesis and computer modeling studies aimed at examining the mode of aminoglycoside binding to APH(3')-IIIa. Specifically, seven site mutants were studied, five from the COOH-terminal helix (Asp(261), Glu(262), and Phe(264)), and two additional residues that line the wall of the anionic depression (Tyr(55) and Arg(211)). Using a molecular modeling approach, six ternary complexes of APH(3')-IIIa.ATP with the antibiotics, kanamycin, amikacin, butirosin, and ribostamycin were independently constructed and these agree well with the mutagenesis data. The results obtained show that the COOH-terminal carboxylate of Phe(264) is critical for proper function of the enzyme. Furthermore, these studies demonstrate that there exists multiple binding modes for the aminoglycosides, which provides a molecular basis for the broad substrate- and regiospecificity observed for this enzyme.     

A Random Sequential Mechanism of Aminoglycoside Acetylation by Mycobacterium tuberculosis Eis Protein

An important cause of bacterial resistance to aminoglycoside antibiotics is the enzymatic acetylation of their amino groups by acetyltransferases, which abolishes their binding to and inhibition of the bacterial ribosome. Enhanced intracellular survival (Eis) protein from Mycobacterium tuberculosis (Mt) is one of such acetyltransferases, whose upregulation was recently established as a cause of resistance to aminoglycosides in clinical cases of drug-resistant tuberculosis. The mechanism of aminoglycoside acetylation by MtEis is not completely understood. A systematic analysis of steady-state kinetics of acetylation of kanamycin A and neomycin B by Eis as a function of concentrations of these aminoglycosides and the acetyl donor, acetyl coenzyme A, reveals that MtEis employs a random-sequential bisubstrate mechanism of acetylation and yields the values of the kinetic parameters of this mechanism. The implications of these mechanistic properties for the design of inhibitors of Eis and other aminoglycoside acetyltransferases are discussed.