Wawrzynczak E J, Watson G J, Cumber A J, Henry R V, Parnell G D, Rieber E P, Thorpe P E
Drug Targeting Laboratory, Institute of Cancer Research, Sutton, England.
Cancer Immunol Immunother. 1991;32(5):289-95. doi: 10.1007/BF01789046.
An immunotoxin consisting of ricin A chain linked to the monoclonal antibody M-T151, recognising the CD4 antigen, was weakly toxic to the human T-lymphoblastoid cell line CEM in tissue culture. The incorporation of [3H]leucine by CEM cells was inhibited by 50% at an M-T151--ricin-A-chain concentration (IC50) of 4.6 nM compared with an IC50 of 1.0 pM for ricin. In contrast, immunotoxins made by linking intact ricin to M-T151 in such a way that the galactose-binding sites of the B chain subunit were either blocked sterically by the antibody component or were left unblocked, were both powerfully cytotoxic with IC50 values of 20-30 pM. The addition of ricin B chain to CEM cells treated with M-T151--ricin-A-chain enhanced cytotoxicity by only eight-fold indicating that isolated B chain potentiated the action of the A chain less effectively than it did as an integral component of an intact ricin immunotoxin. Ricin B chain linked to goat anti-(mouse immunoglobulin) also potentiated weakly. Lactose completely inhibited the ability of isolated ricin B chain to potentiate the cytotoxicity of M-T151--ricin-A-chain and partially (3- to 4-fold) inhibited the cytotoxicity of the blocked and non-blocked ricin immunotoxins. Thus, in this system, the galactose-binding sites of the B chain contributed to cell killing regardless of whether isolated B chain was associated with the A chain immunotoxin or was present in blocked or non-blocked form as part of an intact ricin immunotoxin. The findings suggest that the blocked ricin immunotoxin may become unblocked after binding to the target antigen to re-expose the cryptic galactose-binding sites. However, the unblocking cannot be complete because the maximal inhibition of [3H]leucine incorporation by the blocked immunotoxin was only 80% compared with greater than 99% inhibition by the non-blocked immunotoxin.
一种由与单克隆抗体M-T151相连的蓖麻毒素A链组成的免疫毒素,可识别CD4抗原,在组织培养中对人T淋巴母细胞系CEM的毒性较弱。与蓖麻毒素的半数抑制浓度(IC50)为1.0 pM相比,在M-T151-蓖麻毒素A链浓度(IC50)为4.6 nM时,CEM细胞对[3H]亮氨酸的掺入被抑制了50%。相比之下,通过将完整的蓖麻毒素与M-T151相连制成的免疫毒素,其B链亚基的半乳糖结合位点要么被抗体成分空间位阻,要么保持未被阻断,这两种免疫毒素均具有强大的细胞毒性,IC50值为20-30 pM。将蓖麻毒素B链添加到用M-T151-蓖麻毒素A链处理的CEM细胞中,细胞毒性仅增强了8倍,这表明分离的B链增强A链作用的效果不如其作为完整蓖麻毒素免疫毒素的组成部分时有效。与山羊抗(小鼠免疫球蛋白)相连的蓖麻毒素B链增强作用也较弱。乳糖完全抑制了分离的蓖麻毒素B链增强M-T151-蓖麻毒素A链细胞毒性的能力,并部分(3至4倍)抑制了被阻断和未被阻断的蓖麻毒素免疫毒素的细胞毒性。因此,在该系统中,无论分离的B链是与A链免疫毒素结合,还是以被阻断或未被阻断的形式作为完整蓖麻毒素免疫毒素的一部分存在,B链的半乳糖结合位点都有助于细胞杀伤。这些发现表明,被阻断的蓖麻毒素免疫毒素在与靶抗原结合后可能会解除阻断,从而重新暴露隐蔽的半乳糖结合位点。然而,这种解除阻断不可能是完全的,因为被阻断的免疫毒素对[3H]亮氨酸掺入的最大抑制率仅为80%,而未被阻断的免疫毒素的抑制率则大于99%。