Development of an Abbott ARCHITECT cyclosporine immunoassay without metabolite cross-reactivity.

OBJECTIVE: We investigated the mechanism by which the ARCHITECT cyclosporine (CsA) chemiluminescent microparticle immunoassay (CMIA) eliminates cross-reactivity to CsA metabolites AM1 and AM9, despite its use of a monoclonal antibody which shows cross-reactivity in fluorescence polarization immunoassays. DESIGN AND METHODS: The CMIA was accomplished by incubating an extracted blood sample with magnetic microparticles coated with a very low amount of anti-CsA antibody. After a wash step the microparticles were incubated with a chemiluminescent CsA tracer, followed by a second wash step and measurement of chemiluminescence. The reagent concentrations of salt and detergent were optimized to maximize CsA binding and minimize metabolite interference. RESULTS: Elimination of CsA metabolite cross-reactivity was shown using purified metabolites and blood samples containing native CsA metabolites. The CMIA demonstrated precision and sensitivity acceptable for use in a clinical setting. CONCLUSION: We conclude that it is possible to eliminate CsA metabolite immuno-cross-reactivity by careful assay design.

Defined protein conjugates as signaling agents in immunoassays.

BACKGROUND: Conventional methods for conjugation of macromolecules, such as antibodies and reporter groups, typically yield a mixture ranging from unconjugated starting materials to large aggregates. We explored the use of a solid-phase process to allow improved control in conjugation of macromolecules for use in immunodiagnostic reagents. METHODS: Activated components were sequentially delivered to an immobilized core protein, linking in concentric layers. For immunodiagnostic reagents, proteins with the desired signaling properties were added as interior layers and binding proteins were placed in the final surface layer. After assembly, the conjugates were released into solution by cleaving the linker holding the core protein to the support. Conjugates were prepared with use of three different reporter agents: R-phycoerythrin for microsphere fluorescence flow immunoassay, alkaline phosphatase for enzyme immunoassay, and acridinium for magnetic chemiluminescence immunoassay. For each reporter, six conjugates were prepared with various concentrations of both the reporter and an antibody directed against the alpha-subunit of thyroid-stimulating hormone (TSH), and the complexes were tested in appropriate assay formats for measurement of TSH. RESULTS: Products ranged in mass from approximately 1 to approximately 20 MDa. HPLC analysis of the conjugates on a gel-permeation column showed sizes and chromophore contents highly consistent with the intended structures. In appropriate assay formats, the signal generated by a conjugate increased with incubation time, then plateaued at an intensity approximately proportional to the reporter content but relatively independent of the antibody content of the conjugate. The time required to reach this maximum decreased with increasing antibody content. CONCLUSION: The high degree of structural control available with solid-phase assembly and the close correlation of structure with desired function of the resulting conjugates make this an attractive method for preparation of an important class of in vitro diagnostic reagents.

Solid phase assembly of defined protein conjugates.

We have developed a solid-phase procedure for protein-protein conjugation that gives greater control over product size and composition than previous methods. Conjugates are assembled by sequential addition of activated proteins to the support under conditions suitable for maintaining the activity of the proteins. The total number of conjugate units to be prepared is fixed in the first step by the quantity of the first protein absorbed by the support. In each following step, the added protein links only to previously bound protein. The final conjugate is released to solution by cleaving the linker holding the first protein to the support. This stepwise assembly provides uniformly sized conjugates of the desired size and composition with placement of components at the desired positions within the structure. Using this approach, we have prepared a series of conjugates containing R-phycoerythrin as the central protein, with varying quantities of alkaline phosphatase and IgG with expected molecular masses ranging from 1.6 to 11.5 MDa. Size-exclusion chromatography and atomic force microscopy demonstrate homogeneity and control of the conjugate size. In an immunoassay for human thyroid stimulating hormone, the conjugates show signals consistent with their compositions.