A time-resolved fluorescence immunoassay for insulin in rodent plasma.

We describe a time-resolved fluoroimmunoassay (TR-FIA) for quantification of insulin in rodent serum and plasma in the picomolar levels typical of these samples. The method is a solid-phase, sequential saturation assay based on competition of unlabeled insulin and biotinamidocaproyl-labeled insulin for anti-insulin antibody. Europium-labeled streptavidin allows the DELFIA system (Wallac) to be used for detection. The assay is sensitive (0.1 fmol detection limit, EC50 = 58 +/- 3 pM), accurate ( > 95% recovery of 88-880 pM insulin added to the samples), and simple enough to be automated in a 96-well microtiter plate format. Blood samples of 5 microl can be quickly processed and analyzed within a working concentration range of 40-200 pM, allowing direct measurement of insulin levels in rodents from a tail bleed. We used the TR-FIA to assess insulin levels in mouse and rat samples. In studies of streptozotocin-induced diabetes, as well as glucose load experiments, the assay gave results consistent with known literature. The measured insulin levels correlated significantly with values obtained by radioimmunoassay (R2 = 0.996). The intra-assay and inter-assay coefficients of variation were 2.3% and 15%, respectively. We compared results of this assay with an enzyme-linked immunosorbent assay (ELISA) method. The TR-FIA method was comparable to the ELISA but had higher sensitivity and required only one-tenth as much sample. The assay can be performed using commercially available reagents that allow for high sensitivity and practicability.

Synthesis and characterization of insulin-fluorescein derivatives for bioanalytical applications.

Human insulin was labeled with fluorescein isothiocyanate (FITC) and fully characterized to yield four distinct insulin-FITC species. High-performance liquid chromatography and electrospray mass spectrometry were used to determine the extent and location of fluorescein conjugation. By changing the reaction conditions (i.e., pH, time, and FITC/insulin ratio) the selectivity of the fluorescein conjugation was altered, and all conjugates could be separated. The isolated species of insulin-FITC were labeled at the following residues: A1(Gly), B1(Phe), A1(Gly)B1(Phe), and A1(Gly)B1(Phe)B29(Lys). All four insulin-FITC conjugates were then used to develop fluorescence polarization binding assays with monoclonal and polyclonal anti-insulin antibodies. The assay sensitivity differed between the conjugates depending on the site of modification (B1 > A1 > A1B1 > A1B1B29). Also, the type of antibody used had an important role in the binding of insulin-FITC conjugates. Finally, for the first time the biological activity of the four conjugates was demonstrated by an autophosphorylation assay. The positional substitution dramatically affected the biological activity, confirming insights into the residues responsible for the insulin binding region. The B1 conjugate was found to retain almost all biological activity while the A1 and A1B1 conjugates had approximately 10 times lower activity. The trisubstituted species (labeled at A1, B1, and B29) was determined to be least active.

Kinetic stabilization of microtubule dynamics at steady state in vitro by substoichiometric concentrations of tubulin-colchicine complex.

We have analyzed the effects of tubulin-colchicine (TC)-complex on the dynamic instability behavior of bovine brain microtubules at steady state in vitro using video microscopy. Incorporation of low numbers of TC-complexes per microtubule strongly suppressed dynamics at the plus ends by reducing the rate and extent of growing and shortening and by increasing the time microtubules spent in an attenuated state, neither growing nor shortening detectably. In addition, TC-complex strongly suppressed the catastrophe frequency and increased the rescue frequency. At low concentrations (0.02-0.05 microM), TC-complex suppressed dynamics without reducing the polymer mass or the mean microtubule length. Such strong suppression of microtubule dynamics by low TC-complex concentrations in the absence of polymer mass changes demonstrates that microtubule dynamics are more sensitive to the actions of TC-complex than the polymer mass. Significant reduction of polymer mass occurred at relatively high TC-complex concentration (> 0.05 microM). However, the surviving microtubules were extremely stable. Thus, TC-complex stabilizes microtubules even though the microtubules can transiently depolymerize when TC-complex is added. The data also directly establish that kinetic suppression of dynamics by colchicine at low concentrations is effected by a low number of TC-complexes at the microtubule ends.