Luis F. Olguin

Development of quantitative cell-based enzyme assays in microdroplets.

We describe the development of an enzyme assay inside picoliter microdroplets. The enzyme alkaline phosphatase is expressed in Escherichia coli cells and presented in the periplasm. Droplets act as discrete reactors which retain and localize any reaction product. The catalytic turnover of the substrate is measured in individual droplets by monitoring the fluorescence at several time points within the device and exhibits kinetic behavior similar to that observed in bulk solution. Studies on wild type and a mutant enzyme successfully demonstrated the feasibility of using microfluidic droplets to provide time-resolved kinetic measurements.

An integrated device for monitoring time-dependent in vitro expression from single genes in picolitre droplets.

Microdroplets have great potential for high‐throughput biochemical screening. We report the design of an integrated microfluidic device for droplet formation, incubation and screening. Picolitre water‐in‐oil droplets can be stored in a reservoir that contains ∼106 droplets. In this reservoir droplets are stable for at least 6 h, which gives an extended timescale for biochemical experiments. We demonstrate the utility of the system by following the in vitro expression of green fluorescent protein. The high efficiency allows protein expression from a single molecule of DNA template, creating “monoclonal droplets” in which genotype and phenotype are combined in one emulsion compartment.

Controlling the Retention of Small Molecules in Emulsion Microdroplets for Use in Cell-Based Assays

Water-in-oil microdroplets in microfluidics are well-defined individual picoliter reaction compartments and, as such, have great potential for quantitative high-throughput biological screening. This, however, depends upon contents of the droplets not leaking out into the oil phase. To assess the mechanism of possible leaking, the retention of various fluorescein derivatives from droplets formed in mineral oil and stored for hours in a reservoir on chip was studied. Leaking into the oil phase was observed and was shown to be dependent on the nature of the compounds and on the concentration of the silicone-based polymeric surfactant Abil EM 90 used. In experiments in which droplets filled with fluorescein were mixed with droplets filled with only buffer, the rate of efflux from filled droplets to empty droplets was dependent on the number of neighboring droplets of different composition. Buffer droplets with five fluorescein-containing neighbors took up the fluorophore 4.5 times faster than buffer droplets without fluorescein neighbors. The addition of bovine serum albumin (BSA) substantially reduced leaking. A formulation with 5% BSA reduces leaking of the fluorophore from 45% to 3%. Inclusion of BSA enabled experiments to be carried out over periods up to 18 h, without substantial leaking (<5%). We demonstrate the utility of this additive by following the enzymatic activity of alkaline phosphatase expressed by Escherichia coli cells. The ability to reliably compartmentalize genotype (cell) and phenotype (reaction product) is the basis for using microdroplets in directed evolution studies, and the approaches described herein provide a test system for assessing emulsion formulations for such purposes.

Simultaneous determination of gene expression and enzymatic activity in individual bacterial cells in microdroplet compartments.

A microfluidic device capable of storing picoliter droplets containing single bacteria at constant volumes has been fabricated in PDMS. Once captured in droplets that remain static in the device, bacteria express both a red fluorescent protein (mRFP1) and the enzyme, alkaline phosphatase (AP), from a biscistronic construct. By measuring the fluorescence intensity of both the mRFP1 inside the cells and a fluorescent product formed as a result of the enzymatic activity outside the cells, gene expression and enzymatic activity can be simultaneously and continuously monitored. By collecting data from many individual cells, the distribution of activities in a cell is quantified and the difference in activity between two AP mutants is measured.

Efficient Catalytic Promiscuity in an Enzyme Superfamily: An Arylsulfatase Shows a Rate Acceleration of 1013 for Phosphate Monoester Hydrolysis

We report a second catalytic activity of Pseudomonas aeruginosa arylsulfatase (PAS). Besides hydrolyzing sulfate monoesters, this enzyme catalyzes the hydrolysis of phosphate monoesters with multiple turnovers (>90), a k(cat) value of 0.023 s(-1), a K(M) value of 29 microM, and a kcat/K(M) ratio of 790 M(-1) s(-1) at pH 8.0. This corresponds to a remarkably high rate acceleration of 10(13) relative to the nonenzymatic hydrolysis [(k(cat)/K(M))/k(w)] and a transition-state binding constant (K(tx)) of 3.4 pM. Promiscuous phosphatase and original sulfatase activities only differ by a factor of 620 (measured by k(cat)), so the enzyme provides high accelerations for both reactions. The magnitudes and relative similarity of the kinetic parameters suggest that a functional switch from sulfatase to phosphatase activities is feasible, either by gene duplication or by direct evolution via an intermediate enzyme with dual specificity.

A Trojan horse transition state analogue generated by MgF3− formation in an enzyme active site

Identifying how enzymes stabilize high-energy species along the reaction pathway is central to explaining their enormous rate acceleration. β-Phosphoglucomutase catalyses the isomerization of β-glucose-1-phosphate to β-glucose-6-phosphate and appeared to be unique in its ability to stabilize a high-energy pentacoordinate phosphorane intermediate sufficiently to be directly observable in the enzyme active site. Using 19F-NMR and kinetic analysis, we report that the complex that forms is not the postulated high-energy reaction intermediate, but a deceptively similar transition state analogue in which MgF3− mimics the transferring PO3− moiety. Here we present a detailed characterization of the metal ion–fluoride complex bound to the enzyme active site in solution, which reveals the molecular mechanism for fluoride inhibition of β-phosphoglucomutase. This NMR methodology has a general application in identifying specific interactions between fluoride complexes and proteins and resolving structural assignments that are indistinguishable by x-ray crystallography.

Efficient Catalytic Promiscuity for Chemically Distinct Reactions

High catalytic proficiencies observed for the native and promiscuous reaction of the Pseudomonas aeruginosa arylsulfatase (PAS; the picture shows transition states of the two substrates with corresponding binding constants K(tx)) suggest that the trade-off between high activity and tight specificity can be substantially relaxed.

Kinetic analysis of beta-phosphoglucomutase and its inhibition by magnesium fluoride.

The isomerization of beta-glucose-1-phosphate (betaG1P) to beta-glucose-6-phosphate (G6P) catalyzed by beta-phosphoglucomutase (betaPGM) has been examined using steady- and presteady-state kinetic analysis. In the presence of low concentrations of beta-glucose-1,6-bisphosphate (betaG16BP), the reaction proceeds through a Ping Pong Bi Bi mechanism with substrate inhibition (kcat = 65 s(-1), K(betaG1P) = 15 microM, K(betaG16BP) = 0.7 microM, Ki = 122 microM). If alphaG16BP is used as a cofactor, more complex kinetic behavior is observed, but the nonlinear progress curves can be fit to reveal further catalytic parameters (kcat = 74 s(-1), K(betaG1P) = 15 microM, K(betaG16BP) = 0.8 microM, Ki = 122 microM, K(alphaG16BP) = 91 microM for productive binding, K(alphaG16BP) = 21 microM for unproductive binding). These data reveal that variations in the substrate structure affect transition-state affinity (approximately 140,000-fold in terms of rate acceleration) substantially more than ground-state binding (110-fold in terms of binding affinity). When fluoride and magnesium ions are present, time-dependent inhibition of the betaPGM is observed. The concentration dependence of the parameters obtained from fitting these progress curves shows that a betaG1P x MgF3(-) x betaPGM inhibitory complex is formed under the reaction conditions. The overall stability constant for this complex is approximately 2 x 10(-16) M(5) and suggests an affinity of the MgF3(-) moiety to this transition-state analogue (TSA) of < or = 70 nM. The detailed kinetic analysis shows how a special type of TSA that does not exist in solution is assembled in the active site of an enzyme. Further experiments show that under the conditions of previous structural studies, phosphorylated glucose only persists when bound to the enzyme as the TSA. The preference for TSA formation when fluoride is present, and the hydrolysis of substrates when it is not, rules out the formation of a stable pentavalent phosphorane intermediate in the active site of betaPGM.

Detection of Enzyme Inhibitors in Crude Natural Extracts Using Droplet-Based Microfluidics Coupled to HPLC

Natural product screening for new bioactive compounds can greatly benefit from low reagents consumption and high throughput capacity of droplet-based microfluidic systems. However, the creation of large droplet libraries in which each droplet carries a different compound is a challenging task. A possible solution is to use an HPLC coupled to a droplet generating microfluidic device to sequentially encapsulate the eluting compounds. In this work we demonstrate the feasibility of carrying out enzyme inhibiting assays inside nanoliter droplets with the different components of a natural crude extract after being separated by a coupled HPLC column. In the droplet formation zone, the eluted components are mixed with an enzyme and a fluorogenic substrate that permits to follow the enzymatic reaction in the presence of each chromatographic peak and identify those inhibiting the enzyme activity. Using a fractal shape channel design and automated image analysis, we were able to identify inhibitors of Clostridium perfringens neuraminidase present in a root extract of the Pelargonium sidoides plant. This work demonstrates the feasibility of bioprofiling a natural crude extract after being separated in HPLC using microfluidic droplets online and represents an advance in the miniaturization of natural products screening.

Cell Based Biological Assay Using Microfluidics

A microfluidic device has been designed to measure and manipulate microdroplets, in which protein expression is induced in single cells. The device exploits the permeation of water through poly (dimethylsiloxane) (PDMS) in order to keep the concentration of solutes in aqueous picoliter volume microdroplets stored in wells. The device operates by first creating droplets of the water/solute mixture. Next, droplets are transported down channels and then guided into storage wells using surface tension forces. Finally, the solute concentration of each stored droplet is maintained by chemical potential in a reservoir that is separated from the droplets by a thin layer of PDMS through which water, but not the solutes, permeates. We coexpressed two target proteins, alkaline phosphatase (AP) [1] and red fluorescent protein (mRFP1) [2], in single cells while they have been encapsulated in microdroplets. We interrogated the enzymatic activity of AP and the expression of mRFP1 by following the fluorescence of stored droplets.