Gaik Lin Ong

Processing of antibody-radioisotope conjugates after binding to the surface of tumor cells

Background. Previous experiments indicated that most antibodies binding to cell surface antigens are internalized gradually and degraded within lysosomes, with a half‐life of degradation of approximately 1 day, for most antibodies. The research discussed in this article extended our studies to eight additional antibodies reacting with six different antigens, including three antigens anchored in the membrane by glycosyl‐phosphatidylinositol. The authors also tested antibodies labeled with 111indium, as well as 125iodine, to determine whether different radiolabels would be processed differently.

Cytotoxicity with Auger electron‐emitting radionuclides delivered by antibodies

We investigated the in vitro cytotoxic potential of Auger electron‐emitting radionuclides delivered to the cytoplasm or, more specifically, to lysosomes, via antibodies. The antibody (Ab) used was LL1, which is specific for CD74, an epitope of the major histocompatibility complex (MHC) class II antigen invariant chain, Ii, present on the cell surface. It is taken up in large amounts, approximately 107 Ab molecules per cell per day, and delivered to lysosomes. The radioisotopes tested included 111In, 99mTc and 125I. With sufficient specific activity, approximately 10 mCi/mg Ab, all of these isotopes were potent cytotoxic agents. 125I was active only if a “residualizing” form was used, meaning a form that is trapped within cells after catabolism of the Ab to which it was conjugated (conventional oxidative iodination produces a non‐residualizing label). The conjugates of 111In and 99mTc used are known to be residualizing. One hundred percent cell kill in vitro was obtained with 111In and 125I, under conditions in which a non‐reactive control Ab, conjugated in the same way, produced no significant toxicity. 99mTc was also potent and specific, but appeared somewhat less active than the other isotopes under the conditions evaluated. Although few Abs are accreted by cells at the same rate as LL1, it may be possible to use other Abs to deliver similar amounts of radioactivity, if Abs with higher specific activity can be produced. Such conjugated radioisotopes may be useful for attacking tumor cells in vivo, particularly for single cells or micrometastases. Int. J. Cancer 81:985–992, 1999.

The advantage of residualizing radiolabels for targeting B-cell lymphomas with a radiolabeled anti-CD22 monoclonal antibody

CD22 antibodies (Abs) bound to B‐cell lymphomas are known to be internalized and catabolized rapidly. Therefore, it would be expected that use of CD22 as a target for radioimmunotherapy should be enhanced by the use of “residualizing” radiolabels, which are trapped within the cell after catabolism of the Ab to which they had been conjugated. Our study was intended to evaluate this hypothesis using Ab LL2. In initial experiments, we found that LL2 binding was strongly temperature dependent, with approximately 15‐fold greater binding at 37°C than at 0°C. A series of experiments suggested that this difference is due to a conformational change in the antigen at low temperature, so that the LL2 epitope is partially blocked. In vitro, residualizing labels—including 125I‐dilactitol tyramine and 111In‐DTPA—were retained by cells much longer than a conventional iodine label. In vivo, residualizing labels also showed a marked advantage in terms of uptake by Ramos B‐cell lymphoma xenografts in nude mice. However, the absolute Ab uptake by xenografts was quite low, in comparison with results obtained with many carcinoma xenografts, which appears to be due in part to vascular properties of the B‐cell lymphoma xenografts. Int. J. Cancer 71:429‐435, 1997.

Analysis of high complement levels in Mus hortulanus and BUB mice

BUB/BnJ mice were previously identified as having exceptionally potent complement activity, relative to common mouse strains, in the lysis of antibody-coated human tumor cells. We describe herein our investigation into the molecular and genetic basis for this difference between mouse strains, and also our results with wild mice and mouse strains recently derived from the wild, to determine whether low complement levels are characteristic of wild mice. BUB complement was compared with complement from BALB/c and C57BL/6 mice. BUB mice had higher levels of most individual classical pathway components, except for C1, than the other two strains, but the difference was generally only 2-3-fold, so insufficient to fully explain the difference observed with tumor target cells. CH50 titers on antibody-coated sheep erythrocytes also demonstrated only a 2-4-fold difference. However, CH50 titers on antibody-coated human erythrocyte target cells demonstrated a difference similar in magnitude to that seen with human tumor targets. These results suggest that the difference between mouse strains depends partly on the use of human, rather than sheep, target cells. In an assay for alternative complement pathway activity using neuraminidase-treated human erythrocytes as targets, complements of BALB/c and BUB mice were similar in activity, suggesting that the difference between mouse strains is manifested in the early steps of complement activation. Analysis of F1 and backcross mice suggested that the difference in complement level between BUB and BALB/c or C57BL/6 mice is controlled by semi-dominant genes, and cannot be attributed to a single gene. Wild mice and mice recently derived from the wild generally had low complement levels, similar to most laboratory mice. However, three strains of aboriginal mice, including Mus hortulanus (spicilegus) and Mus spretus, had complement levels higher than that of BUB mice, and as high as sera from the rabbit or rat, which are the most potent known complement sources for the lysis of human tumor cells. In comparison with BUB mouse sera, M. hortulanus sera had at least four-fold higher levels of C3, C6, C8 and C9, and some or all of these differences may explain its higher total complement activity. In the lysis of antibody-coated human erythrocytes, M. hortulanus serum was more potent than any other complement source tested, including sera of the guinea pig, rat, rabbit or human. These strains may be useful in investigating the role of complement in various pathological processes, and in investigating the genetic regulation of the complement system.

Rapid blood clearance of mouse IgG2a and human IgG1 in many nude and nu/+ mouse strains is due to low IgG2a serum concentrations.

Abstract We reported previously that the blood clearance of injected mouse IgG2a was extremely rapid in many strains of nude and nu/+ mice. In an attempt to determine the cause of this phenomenon, the levels of endogenous IgG2a in the blood of these mice was assayed. It was found that the serum level of IgG2a was extremely low in many of these mice, below 50 μg/ml, which is 20–100 times lower than the expected normal value. Great heterogeneity between individual mice was observed in their blood level of IgG2a, and there was an excellent correlation between low blood IgG2a levels and rapid clearance of injected IgG2a. Thus, the blood IgG2a levels are so low that a novel, previously undescribed effect occurs, namely the rapid clearance of small amounts of injected IgG2a. The clearance is due primarily to binding sites in the spleen and liver. The low level of endogenous IgG2a is not due to the lack of a thymus, since it occurs in nu/+ as well as nude mice, but can probably be attributed to the very clean environment in which these mice are raised. In assays of sera from approximately 50 mouse strains, low IgG2a levels were found in all nude colonies and also in some normal mouse strains. Some nude mice displayed relatively normal IgG2a clearance rates despite having low levels of endogenous IgG2a. In repeated bleedings of individual mice, IgG2a levels were found to fluctuate greatly. A similar clearance effect was observed with a human IgG1 Ab injected into mice. This rapid clearance of injected IgG, of certain subclasses, represents a practical problem for many experiments in which antibodies are used for diagnosis or therapy, and several methods of circumventing the problem are discussed.

Processing of antibodies bound to B-cell lymphomas and lymphoblastoid cell lines

Previous experiments demonstrated that some human B‐cell lymphoma cell lines were unusual in that antibodies bound to the cell surface dissociated at high levels. This did not occur with non‐B‐cell hematologic tumors or with carcinomas. In this study, additional B‐cell lymphoma and lymphoblastoid (Epstein‐Barr virus‐transformed) cell lines were tested.

Limitations in the use of low pH extraction to distinguish internalized from cell surface-bound radiolabeled antibody

Internalization by cells of radiolabeled protein ligands bound to the cell surface is frequently analyzed by extraction of the cells with low pH buffers. This treatment supposedly strips the ligands from the cell surface, and remaining molecules are considered to be internalized. However, we show herein that: (1) low molecular weight catabolic products that are trapped within lysosomes (residualizing radiolabels) are efficiently extracted by low pH buffers, under the same conditions used to remove cell surface-bound material, and (2) low pH treatment lyses the majority of the cells, as shown with both a nonadherent and an adherent cell line, with the release of most of a (51)Cr label. Still, low pH extraction was effective at demonstrating Ab internalization, as has been demonstrated many times. These effects of low pH treatment may be attributed to the fixative properties of these buffers. Regardless of the mechanism, these data must be taken into consideration in interpreting the results of such experiments.

Processing of antibodies to the MHC class II antigen by B-cell lymphomas: release of Fab-like fragments into the medium.

Lym-1, an anti-MHC class II Ab, displayed a unique processing pathway after binding to the surface of Raji B-lymphoma cells, in which Fab-like fragments were gradually released into the medium. The fragments had reduced interchain disulfide bonds. Fragmentation was markedly reduced by inhibitors of intracellular catabolism, namely ammonium chloride, chloroquine and leupeptin. The capacity of the process was high, and fragmentation of approximately 5x10(6) Ab molecules per cell per day was measured directly, in what can be considered to be a minimum estimate. Five other Abs to the MHC class II antigen were tested similarly on Raji and on three other B-cell lymphomas: none showed the same high level of fragmentation seen with Lym-1 binding to Raji, but significant fragmentation did occur with some of the Abs, particularly EDU-1 and L243. The level of fragmentation depended on the cell line as well as on the particular Ab. The other 5 Abs were all catabolized, to low molecular weight material, much more extensively than Lym-1. Part of the difference between Abs can probably be attributed to the fortuitous, preferential labeling of Lym-1 on the light chain, since the data suggest that the Fc fragment is fully degraded while the Fab-like fragment is released into the supernatant. This pathway of Ab processing is likely to be related to the physiology of the MHC class II antigen, which recycles into a mildly proteolytic intracellular compartment.

Induction of anti-polycation antibodies in H-2s mice by immunization with nuclear antigens

Following administration of certain chemicals (heavy metals or lupus-inducing drugs), H-2s mice produce autoantibodies reacting with various nuclear antigens such as fibrillarin in the nucleolus and histones in chromatin. In the present study, we have immunized A.SW (H-2s) mice and their congenic counterparts A.BY (H-2b) mice with bovine thymus nuclei in Freunds adjuvant. As was previously observed with lupus-prone mice, such active immunization did not elicit antinuclear antibodies in any of the experimental groups. Surprisingly, the A.SW immunized with nuclei in adjuvant developed high titers of IgG antibodies that reacted exclusively with synthetic polycations. We obtained several monoclonal IgG antibodies from these mice and verified that these polycation-reactive antibodies were not directed against a specific nuclear antigen. The genetic analysis of the monoclonal antibodies further confirmed their clonal diversity. The mechanisms leading to the appearance of antibodies reactive with highly basic molecules in A.SW mice may be related to their predisposition to produce autoantibodies to cationic nuclear antigens (fibrillarin, histones) during chemically-induced autoimmunity.

The fate of antibodies and their radiolabels bound to tumor cells in vitro: the effect of cross-linking at the cell surface and of anti-idiotype antibodies.

SummaryIn order to obtain rapid blood clearance of circulating antibodies (Ab) at a desired time, cross-linking reagents such as second Ab are often employed. Such reagents will generally bind to Ab located at the tumor site as well as free Ab, and we therefore investigated whether the cross-linking of Ab bound to the surface of tumor cells affects the processing of those Ab. Cross-linking was induced in various ways: a polyclonal second Ab [rabbit anti-(mouse IgG)], a monoclonal rat anti-(mouse IgG constant region) Ab, and streptavidin used in conjunction with a biotinylated first Ab. Processing was followed for 3 days, to allow nearly all of the bound Ab to reach its ultimate fate. Results depended strongly on the particular first Ab used. Two basic effects were observed. First, the second Ab efficiently prevented the early dissociation of intact Ab from the cell; once the second Ab bound, there was virtually no dissociation of the primary Ab bound to the cells. For most Ab, where only a small proportion of bound Ab dissociated intact, this effect was relatively small. However, for an unusual Ab, where the majority dissociated intact (L6) the effect of a second Ab in prolonging Ab retention by the cell was dramatic. Second, cross-linking sometimes resulted in markedly accelerated internalization and degradation of the bound Ab, coupled with the release of degradation products into the medium. This process resulted in much shorter retention of the radioisotope by the cell. If a “residualizing” radiolabel was used,125I-dilactitoltyramine, which is probably trapped within lysosomes after Ab catabolism, the effect of the second Ab in accelerating loss from the cell was largely prevented. We also tested anti-idiotype Ab as cross-linking reagents. In addition to testing anti-idiotype Ab known to react with the cell-bound primary Ab, we also tested antiidiotype Ab not expected to bind to cell-bound Ab, initially as a negative control. Unexpectedly, all anti-indiotype Ab tested induced rapid release of the primary Ab from the cell. This effect was similar to the effect of a large excess of unlabeled Ab, and we attribute it to the blocking of the free binding site of a “wobbling” Ab, which prevents its rebinding to a second antigen molecule. We conclude that the use of selected anti-idiotype Ab to clear circulating Ab, while not reacting with cell-bound Ab, must be done cautiously. These effects must be taken into consideration in developing procedures that utilize second Ab or other crosslinking agents.