Synthesis, X-ray structure, photophysical properties, and theoretical studies of six-membered cyclometalated iridium(iii) complexes: revisiting Ir(pnbi)2(acac)

We have determined the X-ray structure of Ir(pnbi)2(acac) (pnbi = 2-phenanthren-9-yl-1-phenyl-1H-benzimidazole; acac = acetylacetonate), which exhibits a six-membered metallocycle around the Ir center. This result stands in sharp contrast to previously postulated structures of Ir(pnbi)2(acac), which assumed a five-membered metallocycle. In this paper, we focus on the relative stability of five- and six-membered Ir(C^N) ring structures. DFT calculations of the total energies of Ir-(C^N) complexes indicated that six-membered structures are more stable when bulky substituents are present in the benzimidazole unit. When the phenanthrene group of pnbi was replaced with a naphthalene moiety, DFT calculations predicted that five-membered cycles are more stable than six-membered rings, which was confirmed experimentally by a single-crystal X-ray diffraction analysis. The steric bulk of the phenanthrene-containing polyaromatic ring ligand thus induces greater interligand repulsion between the two ligands, which plays an important role in determining the cyclometalation route. The Ir complexes examined in this study exhibit red emission (λem ≈ 660 nm) with relatively low quantum yields.

Considerable Enhancement of Emission Yields of [Au(CN)2(-)] Oligomers in Aqueous Solutions by Coexisting Cations

The photophysical properties of [Au(CN)2(-)] oligomers in aqueous solutions were investigated as functions of coexisting cations as well as the viscosity and temperature of solutions. A solution of [Au(CN)2(-)] in the concentration range of 0.03-0.2 mol/dm(3) exhibited emission peaks at 460-480 nm because of the presence of oligomers larger than trimers. Although the emission yields (ϕem) of K[Au(CN)2] solutions were <1%, it considerably increased to 43% when 1.0 mol/dm(3) tetraethylammonium chloride (Et4NCl) was added. The lifetimes of the main emission bands were also significantly varied with additional salts, e.g., KCl, 15 ns; Et4NCl, 520 ns. The time-resolved emission measurements of [Au(CN)2(-)] in a water/glycerol mixture indicated that the lifetimes were almost directly proportional to the inverse of the viscosity of the solution. On the other hand, the intrinsic lifetimes of dimers and trimers with weak emission in shorter wavelength regions were very short and independent of the viscosity of the solutions and coexisting cations (dimer, ∼25 ps; trimer, ∼2 ns). These results indicated that the deactivation of the excited-state [Au(CN)2(-)]n oligomers (n ≥ 4) was dominated by the dissociation of the oligomers to a shorter species (dimer or trimer). The hydrophobic interactions between tetraalkylammonium cations and CN ligands remarkably stabilized the larger oligomers and suppressed the dissociation of the excited-state oligomers, which enhanced the emission yield of the oligomers. This work provides a new method of "exciplex tuning" by changing the environment of excited-state [Au(CN)2(-)]n oligomers.

Coherent vibration and ultrafast dynamics upon bond formation in excited dimers of an Au(i) complex

Au–Au bond strengthening in photoexcited dimers of an Au(i) complex is captured in solution as oscillations of femtosecond absorption signals.

A role for isotype-specific binding factors in the regulation of IgA- and IgG-specific responses by the anti/contrasuppressor T cell circuit

Previous studies have shown that the isotype of an antibody response is selected, in part, by the inhibition of isotype-specific suppression. The antisuppressor model predicts that isotype selection is initiated through an interaction between Ag, Ig, and a T cell-derived factor within 6 h of immunization. This report characterizes some of these molecules and their contribution to isotype regulation. Cultures of murine spleen cells stimulated with the T cell-dependent Ag SRBC led to Ag-specific IgG and IgA responses that could be suppressed and then antisuppressed by a molecular complex produced by mixing purified serum Ig with the supernatant of Ag-pulsed macrophages co-cultured with T cells. The supernatants from separate cultures of Ag-pulsed macrophages and rIL-1 alpha stimulated CD4+ T cells, could be pooled and mixed with Ig to produce functional antisuppressive complexes thereby allowing the factors from the different cell types to be studied separately. Adsorption of the co-culture or the rIL-1 alpha stimulated T cell supernatants against monoclonal IgG or IgA, removed IgG and IgA binding factors, respectively, and abrogated the ability to enhance the corresponding isotype. The adherent material could be recovered and used to reconstitute enhancement by the supernatants depleted of the binding factors. When affinity purified IgG or IgA was used as the source of Ig within the antisuppressive complexes, the enhancement of the antibody response was limited to the isotype of the regulatory Ig used to form the complex. Thus, manipulation of the antisuppressive molecules has a predictable effect on isotype selection. Release of isotype-specific binding factors by CD4+ cells by rIL-1 alpha supports the hypothesis that T cell circuits play a role in initiating isotype regulation.

A role for isotype-specific binding factors in the regulation of IgA- and IgG-specific responses by the anti/contrasuppressor T cell circuit

Previous studies have shown that the isotype of an antibody response is selected, in part, by the inhibition of isotype-specific suppression. The antisuppressor model predicts that isotype selection is initiated through an interaction between Ag, Ig, and a T cell-derived factor within 6 h of immunization. This report characterizes some of these molecules and their contribution to isotype regulation. Cultures of murine spleen cells stimulated with the T cell-dependent Ag SRBC led to Ag-specific IgG and IgA responses that could be suppressed and then antisuppressed by a molecular complex produced by mixing purified serum Ig with the supernatant of Ag-pulsed macrophages co-cultured with T cells. The supernatants from separate cultures of Ag-pulsed macrophages and rIL-1 alpha stimulated CD4+ T cells, could be pooled and mixed with Ig to produce functional antisuppressive complexes thereby allowing the factors from the different cell types to be studied separately. Adsorption of the co-culture or the rIL-1 alpha stimulated T cell supernatants against monoclonal IgG or IgA, removed IgG and IgA binding factors, respectively, and abrogated the ability to enhance the corresponding isotype. The adherent material could be recovered and used to reconstitute enhancement by the supernatants depleted of the binding factors. When affinity purified IgG or IgA was used as the source of Ig within the antisuppressive complexes, the enhancement of the antibody response was limited to the isotype of the regulatory Ig used to form the complex. Thus, manipulation of the antisuppressive molecules has a predictable effect on isotype selection. Release of isotype-specific binding factors by CD4+ cells by rIL-1 alpha supports the hypothesis that T cell circuits play a role in initiating isotype regulation.

The isotype of an Ig-containing mediator dictates the isotype of the antibody produced: a novel mechanism of isotype regulation

Within 6 hours after primary immunization the serum of mice contains a unique form of processed antigen which is complexed with immunoglobulin (Ig). These complexes are formed through the mediation of a T cell factor and markedly enhance in vivo the 7s antibody response. They possess potent antisuppressor activity, i.e., they reverse suppression to immunity both in vivo and in vitro. We have been able to generate in vitro complexes containing a single Ig isotype. Such complexes returned the antibody formation in a suppressed culture only for the same Ig isotype as that present in the complexes. Thus, complexes containing IgG2a, induced exclusively IgG2a antibody and those containing IgA returned only the IgA response in the suppressed culture. The selection of a particular isotype for the formation of the complexes is determined by inducer T cells that produce the factor. The spleen contains inducer T cells capable of mediating the formation of complexes with IgG2a or IgA, while the T cells from Peyer's patches can induce the formation only of IgA complexes. The formation of the complexes is the earliest response to antigen in vivo and, according to the data presented here, the type of isotypes to be synthesized during an immune response may be determined as early as 3-6 hours after immunization as a result of the formation of these isotype specific complexes.

A novel mechanism for the selection of isotype-specific antibody responses: the role of intestinal T cells in the regulation of IgA synthesis by the anti-suppressor circuit

Within 6 hr of immunization the serum of mice contains a unique form of processed antigen, which consists of a complex of immunoglobulin (Ig) and antigen formed in the presence of a factor derived from the anti-suppressor inducer T cell. This complex binds to and activates the anti-suppressor effector T cell, which eventually leads to the inhibition of suppressor cell function. Both of these cells are present in the spleen (SPL) and play a role in the regulation of antibody responses. The purpose of these studies was to identify the anti-suppressor T cells in gut-associated lymphoid tissue and compare their function to their splenic counterparts. Inducer cells were detected in the Peyer's patches (PP), mesenteric lymph nodes but not in the intra-epithelial lymphocytes. The effector cells, which take up the complexes, were detected in PP and lamina propria lymphocytes but not in the intraepithelial or mesenteric lymph node lymphocytes. Furthermore, the uptake of the complexes correlated with the presence of T cells bearing Ia antigens. The PP and SPL anti-suppressor cells were compared for their ability to enhance the production of IgA and IgG. The data clearly showed that the product of the inducer cell, and the effector cell it activates, not only enhanced the antigen-specific responses but also selected for isotype-specific antibody responses. Cells from SPL enhanced IgG greater than IgA, whereas cells from PP selected for IgA. Thus, the presence in PP of cells in the anti-suppressor circuit and their ability to selectively promote IgA synthesis suggest that this regulatory mechanism plays a significant role in intestinal immune responses.

Inhibition of antisuppression by the acute murine graft-versus-host reaction

Profound suppression of both humoral and cell-mediated immunity is a significant systemic effect of graft-versus-host reactions. Although no complete explanation has been advanced for this immunosuppression suppressor cells have been implicated. The data presented in this paper indicate that acute GVH reactions in (C57BL/6J X A/J) F1-hybrid mice induced by the injection of A/J cells severely disrupts the function of the antisuppressor T-cell pathway at both its induction and effector stages. Results show that within 3 weeks of induction of the reaction, Ly1+-T antisuppressor inducer cells lose their ability to generate the serum factor that mediates antisuppression. This factor is normally taken up by and activates Ly2+ T cells which then inhibit suppressor T-cell function. The data also reveal that Ly2+ T cells collected 2 weeks after induction lose their ability to be activated by the antisuppressor factor produced in normal mice. These cells are thus unable to function as antisuppressor effector cells. The uptake of the antisuppressor factor by Ly2+ T cells depends on the expression of Ia antigens on the surface of these cells. Experiments have shown that these antigens are absent from the surface of T cells derived from mice with GVH reactions. This finding may provide an explanation for the inability of these cells to function as antisuppressor effectors. Antisuppression is an important T-cell pathway that is intimately associated with the regulation of immune function. It is possible that the immunosuppression arising in mice with GVH reactions may stem, in part, from unopposed suppressor T-cell activity that results from widespread interference by the reaction with a pathway that normally inhibits suppressor cell activity.

Macrophage T cell interaction. Induction in vitro of a mediator with potent antisuppressor activity

A simple in vitro method is described for the induction of a potent mediator that interferes with suppressor cell function. The mediator consists of three easily identifiable components, Ig, class II determinants and antigen, that form a unique complex similar to, or identical with, the complexes detected in vivo within 3-6 h after immunization. The formation of the antisuppressor mediator in vitro takes place in two steps: the first involves a macrophage-T cell interaction which generates an 'intermediate complex' containing antigen and class II determinants. In the second step the addition of immunochemically purified IgG from normal mouse serum to the macrophage-T cell supernate generates potent antisuppressor activity, which is assayed by the conversion of suppression to immunity. It is suggested that the IgG interacts with the 'intermediate complex' giving rise to the final complex identical to that found in vivo 6 h after immunization. No activity is detected when IgG is added to a supernate of antigen-fed macrophages in the absence of T cells. Furthermore, the T cell plays an additional important role in the formation of the final complexes since it restricts the source of the IgG that will generate the antisuppressor activity. In other words the antisuppressor function is detected only if the IgG matches the donor of the T cell in the Igh locus. The T cell involved in the formation of the complex is the Ly1+ subpopulation. This method should allow elucidation of the genetic, cellular and molecular mechanisms in the activation of this important T cell pathway.

Activation in vivo of a major antisuppressor T-cell pathway immediately after immunization. III. T-cell requirements for its induction

Immunogenic stimuli rapidly induce a potent mediator with antisuppressor activity which represents complexes of Ig and antigen. The formation of the complexes depends on the interaction of two T cells both of which bear the Ly1 phenotype. The two T cells can be separated on the basis of their sensitivity to antilymphocytic serum and dependency on the presence of thymus. T cells bearing I region coded determinants are essential for the formation of the mediator.

Activation in vivo of a major antisuppressor T-cell pathway immediately after immunization. I. Its regulation by I-A gene products

It has previously been demonstrated that within 6 hr after immunogenic stimulation the serum of mice contains a unique form of immunogenic antigen which represents complexes of Ig and antigen. The complexes are known to be strongly cytophilic for Ly2+ Ia+ FcR+ T cells and markedly enhance the IgG response. Anti-I-A treatment of mice suppresses the IgG antibody response and results in the generation of antigen specific T suppressor cells (Ts). Furthermore, anti-I-A treatment blocks the induction of the complexes and abolishes the enhancing effect the complexes exert on the IgG antibody response. The 6-hr cytophilic complexes were shown to block the function of Ts and allow a normal IgG response to take place; therefore, they act as mediators of a novel T-cell pathway called antisuppression. The blocking of the induction of the antisuppressor complexes by anti-I-A antibody was at least in part due to an effect on T cells. In conclusion, products of genes of the I-A subregion of the MHC control the activation early after immunization of a T-cell pathway which is called antisuppression since its major function is interference with the expression of suppression. Its early induction (within 6 hr) suggests that antisuppression may play a pivotal role in determining between immunity and unresponsiveness.

Activation in vivo of a major antisuppressor T-cell pathway immediately after immunization. II. T-cell requirements for its expression

Immunogens activate in vivo within 3-6 hr after injection a new and hitherto unrecognized T-cell pathway which interferes with T-cell suppression, therefore called antisuppression. An important soluble mediator with antisuppressor activity is detected in the serum of immunized animals within 3-6 hr. The mediator represents a unique form of complexes of Ig and antigen. The antisuppressor function of the complexes does not represent a direct "neutralizing" effect of the complexes on the effector T suppressor cells. The antisuppressor complexes activate an Ly2+ T cell which, with the interaction of an Ly123+ T cell, blocks completely T-suppressor-cell function. The biological significance of the T antisuppressor pathway is discussed.