In vivo versus in vitro assays for assessment of T- and B- cell function.

As mice deficient in a particular gene provide an increasing number of novel in vivo models, in vivo assays that examine immune function are becoming a central issue. We found that the sensitivities of in vivo and in vitro assays are strikingly different. These differences have important implications for the interpretation and biological relevance of results

In vivo versus in vitro assays for assessment of T- and B- cell function.

As mice deficient in a particular gene provide an increasing number of novel in vivo models, in vivo assays that examine immune function are becoming a central issue. We found that the sensitivities of in vivo and in vitro assays are strikingly different. These differences have important implications for the interpretation and biological relevance of results

Regulation of IgG antibody titers by the amount persisting of immune-complexed antigen.

Antigens normally induce an immunoglobulin (Ig)G response which stays at an elevated level for several weeks or months, constituting an important part of the immunological memory. This study investigated factors influencing the level of neutralizing IgG titers against a virus and shows that within the range tested it was independent of the number of initially available and potentially responding T helper and B cells, but was regulated by the amount of specific IgG-immune complexes forming depots of persisting antigen. These findings support the notion that the efficiency of vaccines in inducing long-lasting protective IgG is regulated predominantly by the amount of persisting (and presumably follicular dendritic cell-associated) antigen-antibody complexes

Regulation of IgG antibody titers by the amount persisting of immune-complexed antigen.

Antigens normally induce an immunoglobulin (Ig)G response which stays at an elevated level for several weeks or months, constituting an important part of the immunological memory. This study investigated factors influencing the level of neutralizing IgG titers against a virus and shows that within the range tested it was independent of the number of initially available and potentially responding T helper and B cells, but was regulated by the amount of specific IgG-immune complexes forming depots of persisting antigen. These findings support the notion that the efficiency of vaccines in inducing long-lasting protective IgG is regulated predominantly by the amount of persisting (and presumably follicular dendritic cell-associated) antigen-antibody complexes

How many specific B cells are needed to protect against a virus?

The size of the Ab repertoire has been estimated to comprise theoretically somewhere between > 10(10) and approximately 10(4) specificities, dependent on the criteria used. In an attempt to estimate the anti-viral protective Ab repertoire of the mouse the B cell and Ab-forming cell (AFC) frequencies and protective neutralizing Ab levels during the course of an infection with vesicular stomatitis virus (VSV) were analyzed. Determination of AFC frequencies, limiting dilution assays, and adoptive transfer experiments to SCID mice revealed that during the acute phase (day 8) of the immune response, more than 50% of all IgG2a-producing AFCs were specific for VSV, most of them recognizing the neutralizing determinant. In a later phase (days 21 or 50), 10 to 20 times fewer VSV-specific AFCs were present, corresponding to a frequency of approximately 1:10(4) spleen cells. Finally, in a protection assay in SCID mice, adoptively transferred protective Ab concentrations were found to be approximately 1 to 10 micrograms Ab/ml mouse serum. Because during the memory phase of the anti-VSV response usually 10(4) AFC/mouse are engaged to maintain a high level of memory IgG against the neutralizing determinant on VSV and if one assumes a total number of about 10(6) AFCs/mouse, these data suggest a rather limited neutralizing anti-viral protective memory-AFC repertoire of 10(2) to 10(4) different specificities

Free recirculation of memory B cells versus antigen-dependent differentiation to antibody-forming cells.

This study investigated whether or not the localization of persisting Ag influenced the localization of memory B and/or of Ab-forming cells (AFC). As a model Ag, we used vesicular stomatitis virus, which does not measurably replicate extraneuronally in adult mice after peripheral infection. Our results show that memory B cells and AFC are induced at the site where Ag is present; induced memory B cells then recirculate throughout the lymphoid system independently of Ag localization. In contrast, AFC are induced only at the sites of Ag persistence. These triggered Ab producing cells do not recirculate through the lymphoid tissue but migrate to the bone marrow

Free recirculation of memory B cells versus antigen-dependent differentiation to antibody-forming cells.

This study investigated whether or not the localization of persisting Ag influenced the localization of memory B and/or of Ab-forming cells (AFC). As a model Ag, we used vesicular stomatitis virus, which does not measurably replicate extraneuronally in adult mice after peripheral infection. Our results show that memory B cells and AFC are induced at the site where Ag is present; induced memory B cells then recirculate throughout the lymphoid system independently of Ag localization. In contrast, AFC are induced only at the sites of Ag persistence. These triggered Ab producing cells do not recirculate through the lymphoid tissue but migrate to the bone marrow