Antigen modulation of antibody forming cells: the relationship between direct plaque size, antibody secretion rate and antibody affinity.

Using the mathematical theory of direct plaque growth, we have analyzed the expected variation of plaque size with IgM affinity and secretion rate. We use the theory to comment on recent effector cell blockage experiments and show how the theory can be used to determine the change in the secretion rate of a single antibody-forming cell subjected to blockage by a multivalent antigen. We also argue, using the mathematical theory, that under the usual experimental conditions employed in the plaque assay, cells that produce low affinity IgM antibodies will give rise to smaller plaques than cells that produce high affinity IgM antibodies.     

Thymus-independent anti-DNP antibody responses to DNP-casein and DNP-gelatin.

Although studies on the molecular nature of thymus-independent antigens suggested that the polymeric structure with repeated antigenic determinants and slow metabolism are responsible for thymus-independence, we found that anti-DNP antibody responses to DNP-casein and DNP-gelatin were thymus-independent as well as macrophage-independent. These antibody responses were not affected by in vivo treatment with carrageenan or anti-thymocyte serum. In addition, responses of athymic nude mice to both antigens did not show any significant differences when compared with heterologous nu/+ mice. The findings were confirmed by in vitro experiments; non-adherent spleen cells or T cell-depleted spleen cells responded well to both antigens to the same extent as normal spleen cells. Since both casein and gelatin are polyclonal B cell activators and are not presumed to be high polymer or slow-metabolizing substances, we suggest that thymus-independence in many kinds of antibody response should be reconsidered.     

The kinetics of hemolytic plaque formation. IV. IgM plaque inhibition.

An analysis of the inhibition of hemolytic plaques formed against IgM antibodies is presented. The starting point is the equations of DeLisi &; Bell (1974) which describe the kinetics of plaque growth, and DeLisi &; Goldstein (1975) which describe inhibition of IgG plaques. However, the physical chemical models which were used previously to describe IgG inhibition data are shown to be inadequate for describing the characteristics of IgM inhibition curves. Moreover, it is shown that the experimental results place severe restrictions on the possible choices of physical chemical models for IgM upon which to base the calculations. It is argued that in order to account even qualitatively for all the data, one must assume (1) a very restricted motion of IgMs about the Fab hinge region and (2) a very narrow secretion rate distribution of IgM by antibody secreting cells.     

Influence of functional groups on homologous antibody affinity of 11 alpha-hydroxyprogesterone derivatives. I. Synthesis and affinity evaluation

Syntheses and cross-reactivities with progesterone toward the same specific antibody are reported for a series of amides of 11 alpha-hydroxyprogesterone 11-hemisuccinate. Some hypotheses are made regarding the effects of the chemical structure of the substituents on the immunological properties of derivatives.     

Relationship between hybridoma growth and monoclonal antibody production.

Factors affecting cell growth and antibody production in a mouse hybridoma were investigated. Antibody was produced during the growth and decline phases of a batch culture with an increase in the specific rate of antibody production during the decline phase. The specific rate of antibody production was also increased in cells arrested by 2 mM thymidine, suggesting that cell proliferation and antibody production can be uncoupled. Reduced serum concentrations resulted in lower cell growth rates but increased antibody production rates. However, this trend was reversed in hybridomas which had been arrested by thymidine, since the highest antibody production rate was associated with high serum concentrations. Likewise, in proliferating cells, the optimum pH for antibody production (pH 6.8) was lower than the optimum pH for cell growth (pH 7.2), whereas in thymidine-blocked cells, the highest antibody production rate was at pH 7.2. High antibody production rates and product yields were also associated with low growth rates in continuous cultures. The possibility that antibody was under cell cycle control was investigated in synchronized hybridoma cultures. Antibody production occurred during G1 and G2 with a decline in the M phase and evidence of a further decline in the S phase. Thus antibody production was not restricted to the G1 and S phase in this hybridoma.     

Relationship between receptor/ligand binding affinity and adhesion strength.

Receptor-mediated cell adhesion is a central phenomenon in many physiological and biotechnological processes. Mechanical strength of adhesion is generally presumed to be related to chemical affinity of receptor/ligand bonds, but no experimental study has been previously directed toward this issue. Here we investigate the dependence of receptor/ligand adhesion strength on bond affinity using a radial fluid flow chamber assay to measure the force needed to detach polystyrene beads covalently coated with immunoglobulin G from glass surfaces covalently coated with protein A. A spectrum of animal species sources for immunoglobulin G permits examination of three decades of protein A/immunoglobulin G binding affinity. Our results for this model system demonstrate that adhesion strength varies with the logarithm of the binding affinity, consistent with a prediction from the theoretical model by Dembo et al. (Dembo, M., D.C. Torney, K. Saxman, and D. Hammer. 1988. Proc. R. Soc. Lond. Ser. B 234:55-83).     

The hemolytic plaque assay: theory for finite layers.

We extend the mathematical theory of hemolytic plaque growth to include plaques produced by cells secreting antibodies in layers of finite thickness. Previous theories have assumed that the layer was either two-dimensional or of infinite thickness. By using the method of images we derive an equation for the plaque radius as a function of time for layers of any thickness. We show that at short times and at long times the equation reduces to the appropriate infinite three-dimensional and two-dimensional limiting forms, and obtain expressions for estimating the range of times for which these limiting results are valid. For the liquid monolayer technique we obtain a new limiting result. The equation for the plaque radius is a transcendental equation which we solve numerically for a number of cases of interest. These results illustrate a variety of different features of plaque growth associated with the finite thickness of the layer. Experimental studies are usually carried out in layers whose thicknesses are not standardized. In the assays commonly used the thickness h can vary more than six hundred fold, i.e. 1 × 10^?3 cm ?h? 6.5 × 10^?1 cm. Such variation in h will cause widely different kinetics of plaque growth. For typical plaque experiments of one hour duration the two-dimensional limit is valid when h ? 3 × 10^?3 cm while the infinite thickness limit is valid when h? 10^?1 cm. For thicknesses in between these values the finite layer results must be used.     

Numbers and avidity of anti-DNP antibody plaques in different inbred mouse strains

Spleen cells of mice from eight inbred strains and three F₁ hybrids, undergoing a secondary immune response to dinitrophenylated keyhole limpet hemocyanin (DNP-KLH), were examined for numbers of indirect DNP-specific plaque forming cells (PFC) as well as avidity of anti-DNP antibodies. The results indicated that the magnitude of the immune response is under genetic control. Differences in average avidity and heterogeneity of avidity were found among different mouse strains, suggesting genetic control of these parameters. However, no simple pattern of inheritance for these characteristics emerged from the study.     

Relationship between the hemolytic action of heavy metals and lipid peroxidation

It is well known that some of the heavy metals have a hemolytic action, but the mechanisms responsible for this effect are not well established. In order to elucidate whether or not the hemolytic action of heavy metal ions is associated with the peroxidation of membrane lipids, the relationship between metal-induced hemolysis and the generation of malonaldehyde has been studied.The results obtained show that metal-induced hemolysis is associated with the development of peroxidative processes in erythrocyte membranes. The peroxidation is caused by metals with and without pro-oxidant catalytic action. The level of the malonaldehyde products rises before the appearance of hemolysis which proves that the development of peroxidative processes precedes but does not result from hemolysis.The suggestion has been made that the peroxidation of membrane lipids is a possible mechanism of damage to the red cell membrane in metal-induced hemolysis.     

Relationship between the affinity and proteolysis of the insulin receptor. Evidence that higher affinity receptors are preferentially degraded

125I-Insulin binding to rat liver plasma membranes initiated two processes that occurred with similar time courses: an increase of receptor affinity for hormone and degradation of the Mr 135,000 alpha subunit of the insulin receptor to a fragment of Mr 120,000. Inhibitors of serine proteinases prevented alpha subunit degradation without affecting the affinity change. This shows that the change of affinity is not produced by receptor proteolysis and that the intact alpha subunit of the insulin receptor can exist as a higher or lower affinity species. Hormone binding was much more rapid than receptor proteolysis and the initial rate of alpha subunit degradation was independent of the concentration of occupied lower affinity receptors. Only persistent hormone binding and the accumulation of higher affinity insulin-receptor complexes led to significant receptor proteolysis. As the incubation time between 125I-insulin and membranes increased, the rate at which hormone dissociated from Mr 135,000 complexes diminished, whereas hormone dissociated from Mr 120,000 complexes slowly after brief or extended incubations. These observations suggest that 125I-insulin binds to membranes to form low affinity complexes that are not substrates for proteolysis. A slow conformational change produces higher affinity hormone-receptor complexes that are selectively degraded. Thus, the conversion between states of affinity may play a role in the regulation of receptor proteolysis and, consequently, insulin action in cells.