Dehydration is catalyzed by glutamate-136 and aspartic acid-135 active site residues in Escherichia coli dTDP-glucose 4,6-dehydratase.

The dTDP-glucose 4,6-dehydratase catalyzed conversion of dTDP-glucose to dTDP-4-keto-6-deoxyglucose occurs in three sequential chemical steps: dehydrogenation, dehydration, and rereduction. The enzyme contains the tightly bound coenzyme NAD(+), which mediates the dehydrogenation and rereduction steps of the reaction mechanism. In this study, we have determined that Asp135 and Glu136 are the acid and base catalysts, respectively, of the dehydration step. Identification of the acid catalyst was performed using an alternative substrate, dTDP-6-fluoro-6-deoxyglucose (dTDP-6FGlc), which undergoes fluoride ion elimination instead of dehydration, and thus does not require protonation of the leaving group. The steady-state rate of conversion of dTDP-6FGlc to dTDP-4-keto-6-deoxyglucose by each Asp135 variant was identical to that of wt, in contrast to turnover using dTDP-glucose where differences in rates of up to 2 orders of magnitude were observed. These results demonstrate Asp135's role in protonating the glucosyl-C6(OH) during dehydration. The base catalyst was identified using a previously uncharacterized, enzyme-catalyzed glucosyl-C5 hydrogen-solvent exchange reaction of product, dTDP-4-keto-6-deoxyglucose. Base catalysis of this exchange reaction is analogous to that occurring at C5 during the dehydration step of net catalysis. Thus, the decrease in the rate of catalysis ( approximately 2 orders of magnitude) of the exchange reaction observed with Glu136 variants demonstrates this residue's importance in base catalysis of dehydration.

Probing catalysis by Escherichia coli dTDP-glucose-4,6-dehydratase: identification and preliminary characterization of functional amino acid residues at the active site.

A model of the Escherichia coli dTDP-glucose-4,6-dehydratase (4,6-dehydratase) active site has been generated by combining amino acid sequence alignment information with the 3-dimensional structure of UDP-galactose-4-epimerase. The active site configuration is consistent with the partially refined 3-dimensional structure of 4,6-dehydratase, which lacks substrate-nucleotide but contains NAD(+) (PDB file ). From the model, two groups of active site residues were identified. The first group consists of Asp135(DEH), Glu136(DEH), Glu198(DEH), Lys199(DEH), and Tyr301(DEH). These residues are near the substrate-pyranose binding pocket in the model, they are completely conserved in 4,6-dehydratase, and they differ from the corresponding equally well-conserved residues in 4-epimerase. The second group of residues is Cys187(DEH), Asn190(DEH), and His232(DEH), which form a motif on the re face of the cofactor nicotinamide binding pocket that resembles the catalytic triad of cysteine-proteases. The importance of both groups of residues was tested by mutagenesis and steady-state kinetic analysis. In all but one case, a decrease in catalytic efficiency of approximately 2 orders of magnitude below wild-type activity was observed. Mutagenesis of each of these residues, with the exception of Cys187(DEH), which showed near-wild-type activity, clearly has important negative consequences for catalysis. The allocation of specific functions to these residues and the absolute magnitude of these effects are obscured by the complex chemistry in this multistep mechanism. Tools will be needed to characterize each chemical step individually in order to assign loss of catalytic efficiency to specific residue functions. To this end, the effects of each of these variants on the initial dehydrogenation step were evaluated using a the substrate analogue dTDP-xylose. Additional steady-state techniques were employed in an attempt to further limit the assignment of rate limitation. The results are discussed within the context of the 4,6-dehydratase active site model and chemical mechanism.

Characterization of enzymatic processes by rapid mix-quench mass spectrometry: the case of dTDP-glucose 4,6-dehydratase.

The single-turnover kinetic mechanism for the reaction catalyzed by dTDP-glucose 4,6-dehydratase (4,6-dehydratase) has been determined by rapid mix-chemical quench mass spectrometry. Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) was employed to analyze quenched samples. The results were compatible with the postulated reaction mechanism, in which NAD(+) initially oxidizes glucosyl C4 of dTDP-glucose to NADH and dTDP-4-ketoglucose. Next, water is eliminated between C5 and C6 of dTDP-4-ketoglucose to form dTDP-4-ketoglucose-5,6-ene. Hydride transfer from NADH to C6 of dTDP-4-ketoglucose-5,6-ene regenerates NAD(+) and produces the product dTDP-4-keto-6-deoxyglucose. The single-turnover reaction was quenched at various times on the millisecond scale with a mixture of 6 M guanidine hydrochloride and sodium borohydride, which stopped the reaction and reductively stabilized the intermediates and product. Quantitative MALDI-TOF MS analysis of the quenched samples allowed the simultaneous observation of the disappearance of substrate, transient appearance and disappearance of dTDP-hexopyranose-5,6-ene (the reductively stabilized dTDP-4-ketoglucose-5,6-ene), and the appearance of product. Kinetic modeling of the process allowed rate constants for most of the steps of the reaction of dTDP-glucose-d(7) to be evaluated. The transient formation and reaction of dTDP-4-ketoglucose could not be observed, because this intermediate did not accumulate to detectable concentrations.

Kinetic mechanism of nicotinic acid phosphoribosyltransferase: implications for energy coupling.

Nicotinic acid phosphoribosyltransferase (NAPRTase; EC 2.4.2.11) is a facultative ATPase that uses the energy of ATP hydrolysis to drive the synthesis of nicotinate mononucleotide and pyrophosphate from nicotinic acid (NA) and phosphoribosyl pyrophosphate (PRPP). To learn how NAPRTase uses this hydrolytic energy, we have further delineated the kinetic mechanism using steady-state and pre-steady-state kinetics, equilibrium binding, and isotope trapping. NAPRTase undergoes covalent phosphorylation by bound ATP at a rate of 30 s-1. The phosphoenzyme (E-P) binds PRPP with a KD of 0.6 microM, a value 2000-fold lower than that measured for the nonphosphorylated enzyme. The minimal rate constant for PRPP binding to E-P is 0.72 x 10(5) M-1 s-1. Isotope trapping shows that greater than 90% of bound PRPP partitions toward product upon addition of NA. Binding of NA to E-P.PRPP is rapid, kon >/= 7.0 x 10(6) M-1 s-1, and is followed by rapid formation of NAMN and PPi, k >/= 500 s-1. After product formation, E-P undergoes hydrolytic cleavage, k = 6.3 s-1, and products NAMN, PPi, and Pi are released. Quenching from the steady state under Vmax conditions indicates that slightly less than half the enzyme is in phosphorylated forms. To account for this finding, we propose that one step in the release of products is as slow as 5.2 s-1 and, together with the E-P cleavage step, codetermines the overall kcat of 2.3 s-1 at 22 degrees C. Energy coupling by NAPRTase involves two strategies frequently proposed for ATPases of macromolecular recognition and processing. First, E-P has a 10(3)-fold higher affinity for substrates than does nonphosphorylated enzyme, allowing the E-P to bind substrate from low concentration and nonphosphorylated enzyme to expel products against a high concentration. Second, the kinetic pathway follows "rules" [Jencks, W. P. (1989) J. Biol. Chem. 264, 18855-18858] that minimize unproductive alternative reaction pathways. However, an analysis of reaction schemes based on these strategies suggests that such nonvectorial reactions are intrinsically inefficient in ATP use.

Conversion of a cosubstrate to an inhibitor: phosphorylation mutants of nicotinic acid phosphoribosyltransferase.

Nicotinic acid phosphoribosyltransferase (NAPRTase; EC 2.4.2.11) forms nicotinic acid mononucleotide (NAMN) and PPi from 5-phosphoribosyl 1-pyrophosphate (PRPP) and nicotinic acid (NA). The Vmax NAMN synthesis activity of the Salmonella typhimurium enzyme is stimulated about 10-fold by ATP, which, when present, is hydrolyzed to ADP and Pi in 1:1 stoichiometry with NAMN formed. The overall NAPRTase reaction involves phosphorylation of a low-affinity form of the enzyme by ATP, followed by generation of a high-affinity form of the enzyme, which then binds substrates and produces NAMN. Hydrolysis of E-P then regenerates the low-affinity form of the enzyme with subsequent release of products. Our earlier studies [Gross, J., Rajavel, M., Segura, E., and Grubmeyer, C. (1996) Biochemistry 35, 3917-3924] have shown that His-219 becomes phosphorylated in the N1 (pi) position by ATP. Here, we have mutated His-219 to glutamate and asparagine and determined the properties of the purified mutant enzymes. The mutant NAPRTases fail to carry out ATPase, autophosphorylation, or ADP/ATP exchanges seen with wild-type (WT) enzyme. The mutants do catalyze the slow formation of NAMN in the absence of ATP with rates and KM values similar to those of WT. In striking contrast to WT, NAMN formation by the mutant enzymes is competitively inhibited by ATP. Thus, the NAMN synthesis reaction may occur at a site overlapping that for ATP. Previous studies suggest that the yeast NAPRTase does not catalyze NAMN synthesis in the absence of ATP. We have cloned, overexpressed, and purified the yeast enzyme and report its kinetic properties, which are similar to those of the bacterial enzyme.

Learning nursing process: a group project.

The group care plan strategy worked well with a mother and child as clients for a "child" course. It could be used with a pregnant client in a class on childbearing, or with an adult or geriatric person in other classes. Recent graduates of the program or retired or unemployed nurses might serve as models. Because of shrinking resources in nursing education today, efficient and effective strategies that meet learning needs of students and time constraints of faculty are essential. New ways of thinking about teaching are exciting and help to meet educational needs in today's fast-paced environment.

A creative clinical education model: three views.

To effectively educate nurses who are able to meet changing health care needs, new models for clinical experiences must be considered. Collaborative arrangements between practice and education are particularly useful. The preceptor approach is used widely for seasoned students in senior experiences nearing graduation. The "paired" model, a variation on the preceptor model, has worked well in one setting for beginning students. It needs to be tried in other settings with different faculty and perhaps in other types of courses, and it needs to be tested. Collaboration between education and practice not only benefits education, but lays the groundwork for shared scholarly endeavors. Ultimately these relationships have a positive impact on patient care.

Management considerations in the development of a chemical dependency program.

In summary, using an outside firm may be a profitable method to enter a new market quickly with low financial risk. However, there are certain pitfalls in the contracting process. The process should be undertaken with particular attention to the right to re-employ staff. The increasing costs of a per diem fee arrangement as volume grows, and the outside firm's reluctance to move to outpatient services in this type of financial arrangement.