Anton Horn

An Improved Method for Checking HTS/uHTS Liquid-Handling Systems

An efficient method is presented to determine precision and accuracy of multichannel liquid-handling systems under conditions near to application. Themethod consists of gravimetrical determination of accuracy and optical determination of precision based on the dilution of absorbing and fluorescent dye solutions in microplates. Mean delivery volume per well can be determined with precision better than a 0.04% coefficient of variation (CV). Optical signal precision, CV(S), is improved by multiwavelength measurements. Precision of absorbance measurement yields a better resolution than precision of fluorescence measurement (0.3% and 1.5%, respectively), indicating that absorbance measurements should be preferred. From CV(S), an upper bound of the precision of the volumes delivered is derived. Method performance is demonstrated with the dispenser CyBi™-Drop and the pipettor CyBi™-Well using different ejection principles; with commonly used fluids; with 96-, 384-, and 1536-well microplates; and with photometric and fluorometric indicators. Precision of the volumes delivered, as obtained with optimized methods, all plate formats, and both devices, is better than 2% CV with 2 µ L set volume and about 1% CV with higher set volumes.

Alkaline phosphatase of the calf intestine hydrolyzes phospholipids

Pure alkaline phosphatase of the calf intestine is able to hydrolyze phosphatidylinositol 4,5‐diphosphate (TPI) to phosphatidylinositol and Pi and to dephosphorylate phosphatidic acid. This phosphomonoesterase activity shows a considerably high specifie activity when an incubation medium at neutral pH containing 3 mM deoxycholate is used. The activity is inhibited by low concentrations of Ca2+. The enzyme has no detectable phosphodiesterase activity under the conditions tested.

UV measurements in microplates suitable for high-throughput protein determination.

An UV spectrophotometric method for protein determination using microplates is described. Using the SPECTRAmax PLUS reader, the UVStar 96- and 384-well microplates and a 96 or 384 parallel channel liquid handling technique, large-scale determinations can be performed with intraassay precision better than 3% CV (coefficient of variation) in the range from 1 to 8000 microg of protein/ml, measuring at 205, 215, and 280 nm and using different volume-dependent light-path lengths. Since the absorbance coefficient at 205 nm is found to be 30 ml/(mgxcm) for eight different proteins with a CV of 5.6% only with the Path Check option of the reader, protein concentration can be determined without any individual calibration. Samples in the volume range of 60-250 microl can be analyzed without time-consuming and expensive treatment and without sample loss. Using a special 96 or 384 parallel dialyzing device, low molecular weight substances which interfere with the analysis by their UV absorbance, such as buffers and detergents, can effectively be removed. Application examples for serum protein separation are also shown in the presence of the strongly UV absorbing detergent Triton X-100.

Glycosylphosphatidylinositol-specific phospholipase D in blood serum: is the liver the only source of the enzyme?

In cases of systemic inflammatory response syndrome, sepsis, and septic shock, the activity of glycosylphosphatidylinositol-specific phospholipase D (GPI-PLD) in serum amounts to 20 to 25% of the activity found in a healthy control group. The activity of serum GPI-PLD is positively correlated with inflammatory markers and counts of monocytes and stab cells (bands) and negatively correlated with polymorphonuclear neutrophils and lymphocytes in severe diseases. This indicates a yet unknown involvement of the inflammatory system in GPI-PLD liberation and suggests that the liver is not the only source of the plasma enzyme. Plasma was shown to contain an effective inhibitor of GPI-PLD which is soluble in organic solvents. Its concentration in capillary plasma is 20-fold higher than in venous plasma. To find possible other sources of plasma GPI-PLD besides the liver, the GPI-degrading activity was measured in different organs of the rat. Product formation was analysed using [125I]TID-labeled GPI-AP.

Newborn screening for galactosemia: ultramicro assay for galactose-1-phosphate-uridyltransferase activity

An enzymatically optimized, miniaturized (20 microl) fluorimetric assay of galactose-1-phosphate-uridyltransferase using dried blood spots for newborn screening is presented. The Beutler reaction principle has been adapted to the microtiter plate technology and acetone/methanol was used for complete deproteinization. A special ultramicro multiwell screening plate resistant to organic solvents has been developed and employed. The assay is simple, sensitive and inexpensive, due to small reagent volumes and the low prices of ultramicro screening plates. The reaction is linear with galactose-1-phosphate-uridyltransferase activity up to 120 min of incubation time. It shows low imprecision and good correlation to a quantitative validation test. For standardization the use of plate means or medians of activity or fluorescence values is proposed. Individual blank measurement prevents false negative assessments.

Biotinidase determination in serum and dried blood spots—high sensitivity fluorimetric ultramicro-assay

A miniaturized quantitative biotinidase assay has been developed using biotin 6-amidoquinoline as substrate and the 100-fold enhanced fluorescence of 6-amidoquinoline measured using apolar solvents. Amidoquinoline is measured after deproteinization by ethanol/acetone using individual standardisation and solvent resistant microtiter plates. The assay was optimized for end point determinations of biotinidase activities in serum and for newborn screening using dried blood spots. Serum activities obtained are closely correlated with values obtained using a quantitative validation method (r=0.96). Analytical sensitivity is around 2% of the mean activity (7.01+/-1.92 nmol/min/ml, mean+/-SD) of a healthy control population. With dried blood spots, a close correlation with values obtained using the Wallac-test kit (r=0.92) was found. Biotinidase activities of a healthy population of 651 newborns amount to 0.2429+/-0.07 nmol/min/ml blood. The analytical sensitivity is close to 1% of the mean activity.

A new graphical method for determining the affinity constants of monoclonal antibodies to enzymes

A new graphical method is presented for determining the affinity constants of antibodies to enzymes. The method does not require purification of reactants or separation steps at equilibrium. The plot 1/v versus [AT]/V - v) ([AT] = total concentration of antibody binding sites, V = enzyme activity measured in the absence, and v = activity measured in the presence, of antibodies) yields straight lines in the case of simple antibody-enzyme interactions. More complex interaction models show different curve shapes, which can be used for model discrimination as shown by computer simulation studies. The applicability of the method was demonstrated by the determination of the affinity constant of the monoclonal antibody IB 10B8 to alkaline phosphatase of calf intestine. This antibody inhibits enzymic activity completely.

Determination of rate constants of monoclonal antibodies to enzymes

A novel graphical method for determining rate constants of the immune reaction of enzyme-inhibiting or -activating antibodies has been evaluated. The experimental determination of kinetic constants does not require purification of antibody and enzyme nor any separation step of bound and free entities. The resultant enzyme activity is used as a measurement of the extent of enzyme-antibody complex formation. The plot ln magnitude of v - v infinity versus t (v = enzyme activity at time t, v infinity = enzyme activity at infinite time) yields straight lines in the case of antibody excess. Slope and vertical intercept of that primary plot can be used for secondary plots to obtain association (k1) and dissociation (k-1) rate constant, the dissociation constant KD of the complex and the residual enzyme activity of the complex (g/f). The suitability of the graphical method has been established experimentally using the mab IB 10B8 (2) which inhibits alkaline phosphatase activity. With the homogeneous assay in the presence of substrate as well as a microassay in the absence of substrate, k1 and g/f were found to be 4.68 x 10(7) M-1 min-1; 3.74 x 10(7) M-1 min-1 and 0.035; 0.107 respectively. For k-1 and KD, only crude estimates could be derived. The method has been tested for model discrimination using computer simulated data.

Characterization of the interaction of alkaline phosphatase with an activity inhibiting monoclonal antibody by progress curve analysis

Using the enzyme activity inhibiting monoclonal antibody IB 10B8 against alkaline phosphatase of calf intestine (AP), the interaction of a macromolecular antigen with the antibody was studied with different reaction conditions and with different conformations of the antigen, i.e. using (i) different pH values, (ii) different temperatures, (iii) different substrate saturation of the enzyme, (iv) different glycosylphosphatidyl-AP (GPI-AP) aggregates, and (v) membrane-bound species. In the case of antibody excess and negligible substrate consumption enzymic product formation proceeds according to [P] = a + b x t - c x exp(-d x t). By direct progress curve fitting and secondary data evaluation using nonlinear regression, omitting numerical derivation and graphic techniques, kinetic constants of the immune reaction have been estimated. The method does not require any artificial labelling nor any separation of bound and free entities. (i) Upon increasing pH from 9.8 to 11.0, the dissociation constant of the enzyme-antibody complex is increased strongly, mainly due to the decreasing association rate constant. (ii) A temperature increase from 25 degrees C to 37 degrees C produces a marked increase of both the association and dissociation rate constant. (iii) To differentiate between the interaction of the antibody with the free (E) and substrate-bound (ES) enzyme, experiments were done at different substrate concentrations. The results were fitted to a model allowing determination of association and dissociation rate constants of the free and substrate-bound enzyme. The inverse variation of association and dissociation rate constants caused by substrate binding produces a marked increase of the dissociation constant of the antibody-enzyme complex. The antibody-bound enzyme shows a nearly three-fold higher Km value and a six-fold lower catalytic constant as compared to the free enzyme. (iv) Investigations of the interaction of the antibody with anchorless AP, different hydrophobic aggregates of purified GPI-AP (fractions II-V). (v) Membrane-bound GPI-AP show that the epitopes of all species are fully accessible to the antibody and not cryptic. Surprisingly the insertion of the GPI-moiety into the membrane and the aggregation of the different GPI-AP fractions II-V seem to improve antibody binding. Such improvement of binding was not found in control experiments with Fab, indicating only for the bivalent antibody a stronger interaction with the multivalent antigen than with the monovalent antigen.