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Disulfide immunotoxin conjugates

SMPT, succinimidyloxycarbonyl-a-methyl-a-(2-pyridyldithio)toluene, contains an NHS ester end and a pyridyl disulfide end similar to SPDP, but its hindered disulfide makes conjugates formed with this reagent more stable (Thorpe et al., 1987) (Chapter 5, Section 1.2). The reagent is especially useful in forming immunotoxin conjugates for in vivo administration (Chapter 21, Section 2.1). A water-soluble analog of this crosslinker containing an extended spacer arm is also commercially available as sulfo-LC-SMPT (Thermo Fisher). [Pg.77]

Figure 21.1 The basic design of an immunotoxin conjugate consists of an antibody-targeting component crosslinked to a toxin molecule. The complexation typically includes a disulfide bond between the antibody portion and the cytotoxic component of the conjugate to allow release of the toxin intracellularly. In this illustration, an intact A-B toxin protein provides the requisite disulfide, but the linkage also may be designed into the crosslinker itself. Figure 21.1 The basic design of an immunotoxin conjugate consists of an antibody-targeting component crosslinked to a toxin molecule. The complexation typically includes a disulfide bond between the antibody portion and the cytotoxic component of the conjugate to allow release of the toxin intracellularly. In this illustration, an intact A-B toxin protein provides the requisite disulfide, but the linkage also may be designed into the crosslinker itself.
Preparation of Immunotoxin Conjugates via Disulfide Exchange Reactions... [Pg.833]

Figure 21.7 An intact A-B subunit toxin molecule may be activated with 2-iminothiolane with good retention of cytotoxic activity. The thiolated toxin then may be conjugated with SPDP-activated antibody to generate the immunotoxin conjugate through a disulfide bond. Figure 21.7 An intact A-B subunit toxin molecule may be activated with 2-iminothiolane with good retention of cytotoxic activity. The thiolated toxin then may be conjugated with SPDP-activated antibody to generate the immunotoxin conjugate through a disulfide bond.
SMPT often is used in place of SPDP for the preparation of immunotoxin conjugates. The hindered disulfide of SMPT has distinct advantages in this regard. Thorpe et al. (1987) showed that SMPT conjugates had approximately twice the half-life in vivo as SPDP conjugates. Antibody-toxin conjugates prepared with SMPT possess a half-life in vivo of up to 22 hours, presumably due to the decreased susceptibility of the hindered disulfide toward reductive cleavage. [Pg.841]

Figure 21.8 SMPT may be used to form immunotoxin conjugates by activation of the antibody component to form a thiol-reactive derivative. Reduction of an A-B toxin molecule with DTT can facilitate subsequent isolation of the A chain containing a free thiol. Mixing the A-chain containing a sulfhydryl group with the SMPT-activated antibody causes immunotoxin formation through disulfide bond linkage. The hindered disulfide of an SMPT crosslink has been found to survive in vivo for longer periods than conjugates formed with SPDP. Figure 21.8 SMPT may be used to form immunotoxin conjugates by activation of the antibody component to form a thiol-reactive derivative. Reduction of an A-B toxin molecule with DTT can facilitate subsequent isolation of the A chain containing a free thiol. Mixing the A-chain containing a sulfhydryl group with the SMPT-activated antibody causes immunotoxin formation through disulfide bond linkage. The hindered disulfide of an SMPT crosslink has been found to survive in vivo for longer periods than conjugates formed with SPDP.
Figure 21.10 Cystamine may be used to make immunotoxin conjugates by a disulfide interchange reaction. Modification of antibody molecules using an EDC-mediated reaction creates a sulfhydryl-reactive derivative. A-chain toxin subunits containing a free thiol can be coupled to the cystamine-modified antibody to form disulfide crosslinks. Figure 21.10 Cystamine may be used to make immunotoxin conjugates by a disulfide interchange reaction. Modification of antibody molecules using an EDC-mediated reaction creates a sulfhydryl-reactive derivative. A-chain toxin subunits containing a free thiol can be coupled to the cystamine-modified antibody to form disulfide crosslinks.
Other reagent systems can be used to form disulfide linkages between antibody and toxin molecules in immunotoxin conjugates. Cystamine can be incorporated into... [Pg.534]

Although the use of these alternative disulfide generating agents has proven successful in some applications, pyridyldisulfide-containing cross-linkers, as discussed previously, by far are more common for producing immunotoxin conjugates. [Pg.536]

See other pages where Disulfide immunotoxin conjugates is mentioned: [Pg.76]    [Pg.186]    [Pg.279]    [Pg.830]    [Pg.831]    [Pg.834]    [Pg.837]    [Pg.841]    [Pg.844]    [Pg.846]    [Pg.84]    [Pg.170]    [Pg.251]    [Pg.253]    [Pg.520]    [Pg.520]    [Pg.524]    [Pg.527]    [Pg.531]    [Pg.531]    [Pg.366]    [Pg.64]    [Pg.150]    [Pg.231]    [Pg.233]    [Pg.500]    [Pg.500]    [Pg.504]    [Pg.507]   
See also in sourсe #XX -- [ Pg.499 ]

See also in sourсe #XX -- [ Pg.499 ]



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