Emerging Approaches for Fluorescence-Based Newborn Screening of Mucopolysaccharidoses.

Interest in newborn screening for mucopolysaccharidoses (MPS) is growing, due in part to ongoing efforts to develop new therapies for these disorders and new screening assays to identify increased risk for the individual MPSs on the basis of deficiency in the cognate enzyme. Existing tests for MPSs utilize either fluorescence or mass spectrometry detection methods to measure biomarkers of disease (e.g., enzyme function or glycosaminoglycans) using either urine or dried blood spot (DBS) samples. There are currently two approaches to fluorescence-based enzyme function assays from DBS: (1) manual reaction mixing, incubation, and termination followed by detection on a microtiter plate reader; and (2) miniaturized automation of these same assay steps using digital microfluidics technology. This article describes the origins of laboratory assays for enzyme activity measurement, the maturation and clinical application of fluorescent enzyme assays for MPS newborn screening, and considerations for future expansion of the technology.

Structural characterization of antibiotic self-immunity tRNA synthetase in plant tumour biocontrol agent.

Antibiotic-producing microbes evolved self-resistance mechanisms to avoid suicide. The biocontrol Agrobacterium radiobacter K84 secretes the Trojan Horse antibiotic agrocin 84 that is selectively transported into the plant pathogen A. tumefaciens and processed into the toxin TM84. We previously showed that TM84 employs a unique tRNA-dependent mechanism to inhibit leucyl-tRNA synthetase (LeuRS), while the TM84-producer prevents self-poisoning by expressing a resistant LeuRS AgnB2. We now identify a mechanism by which the antibiotic-producing microbe resists its own toxin. Using a combination of structural, biochemical and biophysical approaches, we show that AgnB2 evolved structural changes so as to resist the antibiotic by eliminating the tRNA-dependence of TM84 binding. Mutagenesis of key resistance determinants results in mutants adopting an antibiotic-sensitive phenotype. This study illuminates the evolution of resistance in self-immunity genes and provides mechanistic insights into a fascinating tRNA-dependent antibiotic with applications for the development of anti-infectives and the prevention of biocontrol emasculation.

Tales of Dihydrofolate Binding to R67 Dihydrofolate Reductase.

Homotetrameric R67 dihydrofolate reductase possesses 222 symmetry and a single active site pore. This situation results in a promiscuous binding site that accommodates either the substrate, dihydrofolate (DHF), or the cofactor, NADPH. NADPH interacts more directly with the protein as it is larger than the substrate. In contrast, the p-aminobenzoyl-glutamate tail of DHF, as monitored by nuclear magnetic resonance and crystallography, is disordered when bound. To explore whether smaller active site volumes (which should decrease the level of tail disorder by confinement effects) alter steady state rates, asymmetric mutations that decreased the half-pore volume by ∼35% were constructed. Only minor effects on k(cat) were observed. To continue exploring the role of tail disorder in catalysis, 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide-mediated cross-linking between R67 DHFR and folate was performed. A two-folate, one-tetramer complex results in the loss of enzyme activity where two symmetry-related K32 residues in the protein are cross-linked to the carboxylates of two bound folates. The tethered folate could be reduced, although with a ≤30-fold decreased rate, suggesting decreased dynamics and/or suboptimal positioning of the cross-linked folate for catalysis. Computer simulations that restrain the dihydrofolate tail near K32 indicate that cross-linking still allows movement of the p-aminobenzoyl ring, which allows the reaction to occur. Finally, a bis-ethylene-diamine-α,γ-amide folate adduct was synthesized; both negatively charged carboxylates in the glutamate tail were replaced with positively charged amines. The K(i) for this adduct was ∼9-fold higher than for folate. These various results indicate a balance between folate tail disorder, which helps the enzyme bind substrate while dynamics facilitates catalysis.

tRNAs as antibiotic targets.

Transfer RNAs (tRNAs) are central players in the protein translation machinery and as such are prominent targets for a large number of natural and synthetic antibiotics. This review focuses on the role of tRNAs in bacterial antibiosis. We will discuss examples of antibiotics that target multiple stages in tRNA biology from tRNA biogenesis and modification, mature tRNAs, aminoacylation of tRNA as well as prevention of proper tRNA function by small molecules binding to the ribosome. Finally, the role of deacylated tRNAs in the bacterial "stringent response" mechanism that can lead to bacteria displaying antibiotic persistence phenotypes will be discussed.

Plant tumour biocontrol agent employs a tRNA-dependent mechanism to inhibit leucyl-tRNA synthetase.

Leucyl-tRNA synthetases (LeuRSs) have an essential role in translation and are promising targets for antibiotic development. Agrocin 84 is a LeuRS inhibitor produced by the biocontrol agent Agrobacterium radiobacter K84 that targets pathogenic strains of A. tumefaciens, the causative agent of plant tumours. Agrocin 84 acts as a molecular Trojan horse and is processed inside the pathogen into a toxic moiety (TM84). Here we show using crystal structure, thermodynamic and kinetic analyses, that this natural antibiotic employs a unique and previously undescribed mechanism to inhibit LeuRS. TM84 requires tRNA(Leu) for tight binding to the LeuRS synthetic active site, unlike any previously reported inhibitors. TM84 traps the enzyme-tRNA complex in a novel 'aminoacylation-like' conformation, forming novel interactions with the KMSKS loop and the tRNA 3'-end. Our findings reveal an intriguing tRNA-dependent inhibition mechanism that may confer a distinct evolutionary advantage in vivo and inform future rational antibiotic design.

A balancing act between net uptake of water during dihydrofolate binding and net release of water upon NADPH binding in R67 dihydrofolate reductase.

R67 dihydrofolate reductase (DHFR) catalyzes the reduction of dihydrofolate (DHF) to tetrahydrofolate using NADPH as a cofactor. This enzyme is a homotetramer possessing 222 symmetry, and a single active site pore traverses the length of the protein. A promiscuous binding surface can accommodate either DHF or NADPH, thus two nonproductive complexes can form (2NADPH or 2DHF) as well as a productive complex (NADPH.DHF). The role of water in binding was monitored using a number of different osmolytes. From isothermal titration calorimetry (ITC) studies, binding of NADPH is accompanied by the net release of 38 water molecules. In contrast, from both steady state kinetics and ITC studies, binding of DHF is accompanied by the net uptake of water. Although different osmolytes have similar effects on NADPH binding, variable results are observed when DHF binding is probed. Sensitivity to water activity can also be probed by an in vivo selection using the antibacterial drug, trimethoprim, where the water content of the media is decreased by increasing concentrations of sorbitol. The ability of wild type and mutant clones of R67 DHFR to allow host Escherichia coli to grow in the presence of trimethoprim plus added sorbitol parallels the catalytic efficiency of the DHFR clones, indicating water content strongly correlates with the in vivo function of R67 DHFR.

Effects of temperature and viscosity on R67 dihydrofolate reductase catalysis.

R67 dihydrofolate reductase (DHFR) is a novel homotetrameric protein that possesses 222 symmetry and a single, voluminous active site pore. This symmetry poses numerous limitations on catalysis; for example, two dihydrofolate (DHF) molecules or two NADPH molecules, or one substrate plus one cofactor can bind. Only the latter combination leads to catalysis. To garner additional information on how this enzyme facilitates transition-state formation, the temperature dependence of binding and catalysis was monitored. The binding of NADPH and DHF is enthalpy-driven. Previous primary isotope effect studies indicate hydride transfer is at least partially rate-determining. Accordingly, the activation energy associated with transition-state formation was measured and is found to be 6.9 kcal/mol (DeltaH(++)(25) = 6.3 kcal/mol). A large entropic component is also found associated with catalysis, TDeltaS(++)(25) = -11.3 kcal/mol. The poor substrate, dihydropteroate, binds more weakly than dihydrofolate (DeltaDeltaG = 1.4 kcal/mol) and displays a large loss in the binding enthalpy value (DeltaDeltaH = 3.8 kcal/mol). The k(cat) value for dihydropteroate reduction is decreased 1600-fold compared to DHF usage. This effect appears to derive mostly from the DeltaDeltaH difference in binding, demonstrating that the glutamate tail is important for catalysis. This result is surprising, as the para-aminobenzoyl-glutamate tail of DHF has been previously shown to be disordered by both NMR and crystallography studies. Viscosity studies were also performed and confirmed that the hydride transfer rate is not sensitive to sucrose addition. Surprisingly, binding of DHF, by both K(m) and K(d) determination, was found to be sensitive to added viscogens, suggesting a role for water in DHF binding.

Calorimetric studies of ligand binding in R67 dihydrofolate reductase.

R67 dihydrofolate reductase (DHFR) is a novel bacterial protein that possesses 222 symmetry and a single active site pore. Although the 222 symmetry implies that four symmetry-related binding sites must exist for each substrate as well as for each cofactor, various studies indicate only two molecules bind. Three possible combinations include two dihydrofolate molecules, two NADPH molecules, or one substrate plus one cofactor. The latter is the productive ternary complex. To explore the role of various ligand substituents during binding, numerous analogues, inhibitors, and fragments of NADPH and/or folate were used in both isothermal titration calorimetry (ITC) and K(i) studies. Not surprisingly, as the length of the molecule is shortened, affinity is lost, indicating that ligand connectivity is important in binding. The observed enthalpy change in ITC measurements arises from all components involved in the binding process, including proton uptake. As a buffer dependence for binding of folate was observed, this likely correlates with perturbation of the bound N3 pK(a), such that a neutral pteridine ring is preferred for pairwise interaction with the protein. Of interest, there is no enthalpic signal for binding of folate fragments such as dihydrobiopterin where the p-aminobenzoylglutamate tail has been removed, pointing to the tail as providing most of the enthalpic signal. For binding of NADPH and its analogues, the nicotinamide carboxamide is quite important. Differences between binary (binding of two identical ligands) and ternary complex formation are observed, indicating interligand pairing preferences. For example, while aminopterin and methotrexate both form binary complexes, albeit weakly, neither readily forms ternary complexes with the cofactor. These observations suggest a role for the O4 atom of folate in a pairing preference with NADPH, which ultimately facilitates catalysis.

Defining the binding site of homotetrameric R67 dihydrofolate reductase and correlating binding enthalpy with catalysis.

R67 dihydrofolate reductase (DHFR) is a novel protein that possesses 222 symmetry. A single active site pore traverses the length of the homotetramer. Although the 222 symmetry implies that four symmetry-related binding sites should exist for each substrate as well as each cofactor, isothermal titration calorimetry (ITC) studies indicate only two molecules bind. Three possible combinations include two dihydrofolate molecules, two NADPH molecules, or one substrate with one cofactor. The latter is the productive ternary complex. To evaluate the roles of A36, Y46, T51, G64, and V66 residues in binding and catalysis, a site-directed mutagenesis approach was employed. One mutation per gene produces four mutations per active site pore, which often result in large cumulative effects. Conservative mutations at these positions either eliminate the ability of the gene to confer trimethoprim resistance or have no effect on catalysis. This result, in conjunction with previous mutagenesis studies on K32, K33, S65, Q67, I68, and Y69 [Strader, M. B., et al. (2001) Biochemistry 40, 11344-11352; Hicks, S. N., et al. (2003) Biochemistry 42, 10569-10578; Park, H., et al. (1997) Protein Eng. 10, 1415-1424], allows mapping of the active site surface. Residues for which conservative mutations have large effects on binding and catalysis include K32, Q67, I68, and Y69. These residues form a stripe that establishes the ligand binding surface. Residues that accommodate conservative mutations that do not greatly affect catalysis include K33, Y46, T51, S65, and V66. Isothermal titration calorimetry studies were also conducted on many of the mutants described above to determine the enthalpy of folate binding to the R67 DHFR.NADPH complex. A linear correlation between this DeltaH value and log k(cat)/K(m) is observed. Since structural tightness appears to be correlated with the exothermicity of the binding interaction, this leads to the hypothesis that enthalpy-driven formation of the ternary complex in these R67 DHFR variants plays a strong role in catalysis. Use of the alternate cofactor, NADH, extends this correlation, indicating preorganization of the ternary complex determines the efficiency of the reaction. This hypothesis is consistent with data suggesting R67 DHFR uses an endo transition state (where the nicotinamide ring of cofactor overlaps the more bulky side of the substrate's pteridine ring).