S T Smiley

By using a potential-dependent J-aggregate-forming delocalized lipophilic cation, 5,5',6,6'-tetrachloro-1,1',3,3'-tetraethylbenzimidazolocarbocyanine++ + iodide (JC-1), we find that membrane potentials across mitochondria in a living cell can be heterogeneous. Remarkably, even within a long contiguous mitochondrion, regional heterogeneity in membrane potentials appears to be possible.

We have examined whether T cell stimulation by direct or indirect pathways contributes to alloantibody production by B cells after major histocompatibility complex (MHC)-disparate skin graft rejection in mice. Experiments were performed using normal mice, MHC class II-deficient mice, MHC class II-deficient mice with an intact peripheral CD4+ cell population (due to expression of class II antigens only on thymic epithelium), mice lacking the cytoplasmic tail of their MHC class II antigens, and mice depleted of CD4+ cells by anti-CD4 monoclonal antibody treatment. Depletion of recipient CD4+ cells reduced alloantibody production to barely detectable levels. Absence of donor MHC class II antigens did not affect the production of either immunoglobulin (Ig)M or IgG antibodies directed at class I alloantigens. Absence of recipient MHC class II antigens, however, led to production of only IgM but not IgG antibodies, even if the recipients had an intact CD4+ cell population. Absence of the cytoplasmic tail of the recipient's MHC class II antigens led to the production of slightly reduced amounts of IgG antibody. These findings indicate that (a) CD4+ cells are essential helper cells for B cell alloantibody production; (b) production of IgM alloantibody can occur with help from CD4+ cells, which recognize either donor class II antigens or modified recipient class II antigens; (c) isotype switching from IgM to IgG alloantibody requires help from CD4+ cells activated by antigens presented by recipient MHC class II molecules; and (d) the cytoplasmic domain of the recipient MHC class II molecules may be involved in the mechanism that leads to isotype switching by B cells. Thus, there are two levels of CD4-mediated help available for B cells responding to alloantigens: one (involving a noncognate interaction) can produce B cell activation, and a second (involving a cognate interaction) is required for differentiation and IgG alloantibody production.

A strategy for the production of small, soluble, single-chain T-cell receptor (scTCR) fragments that carry an intact TCR antigen-combining site is presented. The rationale is based on structural similarity between TCR and antibody molecules and use of computer modeling methods to derive a model structure of a human scTCR variable (V)-domain dimer. A gene encoding the RFL3.8 TCR protein, specific for the hapten fluorescein in the context of major histocompatibility complex class II and composed of one V alpha and one V beta domain joined via a flexible peptide linker, was assembled in an Escherichia coli plasmid. Subsequently, the protein was produced in a bacterial expression system, purified, refolded, and found to be poorly soluble at neutral pH in aqueous buffers. An inspection of the computer-generated V alpha-V beta domain model showed several surface exposed hydrophobic residues. When these were replaced by water-soluble side chains via site-directed mutagenesis of the corresponding gene, a soluble protein resulted and was shown to have antigen-binding properties equivalent to those of the intact TCR of the RFL3.8 T-cell clone. These results demonstrate the feasibility of obtaining TCR fragments endowed with antigen-combining properties by protein engineering in E. coli.

Dequalinium has previously been shown to be an anticarcinoma agent (M. J. Weiss et al., Proc. Natl. Acad. Sci. USA, 84: 5444-5448, 1987). The present study demonstrates that it can inhibit protein kinase C-beta 1 isolated from an overproducing cell line with a 50% inhibitory concentration of 8-15 microM. Further examination of the inhibition by using structural analogues of dequalinium reveals that the length of the methylene bridge between the two quinaldinium moieties, the presence of the ring substituents, and the bipartite character of the compound each contributes to the inhibitory potency. Related studies show that the analogues display the same rank order of inhibitory potency when tested with the trypsin-generated catalytic fragment of the enzyme, indicating that dequalinium inhibits kinase activity through an interaction with the catalytic subunit. Further studies argue that the ability of a given analogue to inhibit phosphotransferase activity correlates with its ability to compete with [3H]phorbol-12,13-dibutyrate binding on the intact enzyme (50% inhibitory concentration of 2-5 microM). This suggests that the inhibitor is either binding directly to the regulatory subunit as well, or that due to its interaction with the catalytic subunit, dequalinium produces an indirect effect on sites defined by phorbol ester binding. Kinetic analysis revealed that inhibition is noncompetitive with respect to ATP or phosphatidylserine. Studies conducted with types I, II, and III rat brain isozymes, resolved by hydroxylapatite chromatography, demonstrate that dequalinium inhibits each of them with similar potency (50% inhibitory concentration of 11 microM) and imply that the site of contact on the enzyme is a highly conserved region. Morphology studies with dequalinium in intact cells demonstrate that the inhibitor can protect control cells against phorbol ester-induced morphology changes but cannot protect protein kinase C-overproducing cells, suggesting that an elevation in protein kinase C levels alone is sufficient to overturn the protection conferred by dequalinium. On the basis of these results, we propose that protein kinase C could be a critical in vivo target of dequalinium.