Characterization of a Blood Spot Creatine Kinase Skeletal Muscle Isoform Immunoassay for High-Throughput Newborn Screening of Duchenne Muscular Dystrophy.

BACKGROUND: Duchenne muscular dystrophy (DMD) is a progressive, lethal X-linked neuromuscular disorder with an average worldwide incidence of 1:5000. Blood spot creatine kinase (CK) enzyme assays previously used in newborn screening programs for DMD are nonspecific because measured CK enzyme activity is attributable to 3 isoenzyme forms of CK (CK-MM, CK-MB, and CK-BB) and it is the CK-MM isoform that is found predominantly in skeletal muscle. CK-MM is increased in boys with DMD owing to muscle damage. We describe a sensitive and specific automated immunoassay for CK-MM to screen for DMD in blood spots. METHODS: The prototype assay was developed on the PerkinElmer GSP® analyzer to enable high-throughput screening. CK-MM was assayed using a solid phase, 2-site immunofluorometric system. Purified human CK-MM was used to create calibrators and controls. RESULTS: The limit of blank (LOB), detection (LOD), and quantification (LOQ) values were <1, 3, and 8 ng/mL, respectively. The analytical measurement range was 4-8840 ng/mL. Interassay (n = 40) imprecision was <7% across the analytical range. Cross-reactivity was <5% for CK-MB and 0% for CK-BB. The mean recovery of CK-MM was 101% (range 87%-111%). Blood spots from newborn infants (n = 277) had a mean CK-MM concentration of 155 ng/mL and a 99th centile of 563 ng/mL. The mean blood spot CK-MM concentration from 10 cases of DMD was 5458 ng/mL (range 1217-9917 ng/mL). CONCLUSIONS: CK-MM can be reliably quantified in blood spots. The development of this CK-MM assay on a commercial immunoassay analyzer would enable standardized and high-throughput newborn blood spot screening of DMD.

A dissociative fluorescence enhancement technique for one-step time-resolved immunoassays.

The limitation of current dissociative fluorescence enhancement techniques is that the lanthanide chelate structures used as molecular probes are not stable enough in one-step assays with high concentrations of complexones or metal ions in the reaction mixture since these substances interfere with lanthanide chelate conjugated to the detector molecule. Lanthanide chelates of diethylenetriaminepentaacetic acid (DTPA) are extremely stable, and we used EuDTPA derivatives conjugated to antibodies as tracers in one-step immunoassays containing high concentrations of complexones or metal ions. Enhancement solutions based on different ß-diketones were developed and tested for their fluorescence-enhancing capability in immunoassays with EuDTPA-labelled antibodies. Characteristics tested were fluorescence intensity, analytical sensitivity, kinetics of complex formation and signal stability. Formation of fluorescent complexes is fast (5 min) in the presented enhancement solution with EuDTPA probes withstanding strong complexones (ethylenediaminetetra acetate (EDTA) up to 100 mM) or metal ions (up to 200 µM) in the reaction mixture, the signal is intensive, stable for 4 h and the analytical sensitivity with Eu is 40 fmol/L, Tb 130 fmol/L, Sm 2.1 pmol/L and Dy 8.5 pmol/L. With the improved fluorescence enhancement technique, EDTA and citrate plasma samples as well as samples containing relatively high concentrations of metal ions can be analysed using a one-step immunoassay format also at elevated temperatures. It facilitates four-plexing, is based on one chelate structure for detector molecule labelling and is suitable for immunoassays due to the wide dynamic range and the analytical sensitivity.

Minisequencing with acyclonucleoside triphosphates tethered to lanthanide(III) chelates.

Four acyclic nucleoside triphosphates (derivatives of cytosine, thymine, 7-deazaadenine, and 7-deazaguanine) labeled with nonluminescent europium, terbium, dysprosium, and samarium chelates of 2,2',2'',2'''-[[4-(4-isothiocyanatophenyl)ethyl]pyridine-2,6-diyl]bis(methylenenitrilo)]tetrakis(acetic acid) were applied to minisequencing using two mutations (Delta F 508 and 1717-1 G to A) of cystic fibrosis as a model system. When synthetic targets were used, all four alleles involved could be analyzed in a single reaction using four terminating substrates labeled with four different lanthanide(III) chelates and DELFIA technology for detection. Blood spot samples without DNA isolations were used for PCR amplification and genotyping the target mutations by minisequencing. The single- and dual-labeled minisequencing assays were robust, while the four-label assay still requires further optimization of the multiplexed PCR amplification.

Labeling of proteins and oligopeptides with luminescent lanthanide(III) chelates.

Synthesis of a building block that allows introduction of photoluminescent europium(III) and samarium(III) chelates to synthetic oligopeptides on solid phase using standard Fmoc chemistry is described. Upon completion of the oligopeptide synthesis, these conjugates were converted to the corresponding lanthanide(III) chelates by treatment with appropriate lanthanide(III) salt. Also synthesis of a new terpyridine-based europium(III) chelate designed for solution phase protein labeling is demonstrated.

Solid-phase synthesis of oligonucleotides labeled with luminescent lanthanide(III) chelates.

The synthesis of phosphoramidite building blocks that allow introduction of luminescent europium(III), terbium(III), dysprosium(III), and samarium(III) chelates to oligonucleotides on the solid phase is described. Several labeled oligonucleotides using these building blocks were prepared, and the photophysical properties of these bioconjugates were investigated.

Caspase multiplexing: simultaneous homogeneous time-resolved quenching assay (TruPoint) for caspases 1, 3, and 6.

Caspases are a group of cysteine proteases involved in apoptosis and inflammation. A multiparametric homogeneous assay capable of measuring activity of three different caspases in a single well of a microtiter plate is described. Different fluorescent europium, samarium, terbium, and dysprosium chelates were coupled to a caspase substrate peptide, their luminescence properties, were analyzed, and their function in a time-resolved fluorescence quenching-based caspase 3 assay was studied. Substrates for caspases 1, 2, 3, 6, and 8 and granzyme B were also synthesized and their specificities for different caspases were determined. By selecting suitable lanthanide chelates and substrates we developed a multiparametric homogeneous time-resolved fluorescence quenching-based assay for caspases 1, 3, and 6. The assay was capable of measuring the activity of both single caspases and a mixture of three caspases mixed in the same well.

Hybridization properties of support-bound oligonucleotides: the effect of the site of immobilization on the stability and selectivity of duplex formation.

Four 12-mer oligodeoxyribonucleotide sequences were immobilized to uniformly sized (50 microm) polymer particles through C5-tethered thymine and N(4)-tethered cytosine bases at four different sites in each sequence. The effect of the site of immobilization on the efficiency and selectivity of hybridization of the particle-bound probes was quantified by a sandwich-type assay based on a time-resolved fluorometric measurement of an oligonucleotide probe labeled with a photoluminescent europium(III) chelate directly from the surface of a single particle. Immobilization through a base in the central part of the sequence was observed to destablize the duplex more markedly than tethering through a terminal base. The effect of a one-base mismatch on the duplex stability increased with the increasing distance from the site of immobilization.

Synthesis of nonluminescent lanthanide(III) chelates tethered to an aminooxy group and their applicability to biomolecule derivatization.

Synthesis of nonluminescent lanthanide(III) chelates tethered to an aminooxy group (i.e., 1-[4-(6-aminooxyhexamido)benzyl]diethylenetriaminetetraacetic acid lanthanides(III), 6a-d, where Ln(3+) is Eu, Dy, Sm, and Tb) is described. Their applicability to biomolecule derivatization is demonstrated by allowing them to react with a synthetic oligopeptide, a protein, two synthetic drugs, and a steroid. The oligopeptide and protein were linked to 6 after preoxidation of their N-terminal serine residues, while the drugs and the steroid reacted via their ketone functionality. Also some application data is included.

Introduction of lanthanide(III) chelates to oligopeptides on solid phase.

The synthesis of oligopeptide building blocks for the introduction of nonluminescent and luminescent lanthanide(III) chelates to the oligopeptide structure on the solid phase is described. The oligopeptide conjugates synthesized were used in DELFIA-based receptor binding assay (motilin) as well as in LANCE time-resolved fluorescence quenching assay (caspase-3).

Mixed-phase hybridization of short oligodeoxyribonucleotides on microscopic polymer particles: effect of one-base mismatches on duplex stability.

Hybridization of short oligonucleotides (10- and 11-mers) to complementary probes immobilized to microscopic polymer particles was quantified by a sandwich type mixed-phase hybridization assay based on a time-resolved fluorometric measurement of a photoluminescent europium(III) chelate from the surface of a single particle. Among the 54 sequences that were studied, 21 were fully complementary to the particle-bound probes, while 33 contained an internal one-base mismatch. The observed affinities were compared to those predicted by the nearest-neighbor model. In addition, various factors, such as the pore size of the particle, the linker structure, the charge type of the probe, and the efficiency of agitation, that might be expected to affect the kinetics of mixed-phase hybridization have been examined.