Osteoclastic superoxide production and bone resorption: stimulation and inhibition by modulators of NADPH oxidase.

Production of superoxide radicals by osteoclasts is necessary for normal bone degradation. White blood cell superoxide, needed for bacterial killing, is produced by activated NADPH oxidase. Since osteoclasts and white blood cells share a common hematopoietic origin, we initiated experiments to test the hypothesis that superoxide radicals at the osteoclast-bone interface are produced by NADPH oxidase. Diphenyl iodonium (IDP), an inhibitor of NADPH oxidase, blocked superoxide generation and decreased osteoclastic bone resorption in cultures of calvarial explants from normal mice. Interferon (IFN) gamma, a stimulant of NADPH oxidase activity, increased superoxide production and bone resorption in cultures of calvarial explants from osteopetrotic (microphthalmic) mice. IDP blocked the stimulatory effects of IFN in this bone resorption model. These data suggest that osteoclastic superoxide is produced by NADPH oxidase.

Multiple patterns of MHC class II antigen expression on cellular constituents of rat heart grafts. Lack of correlation with graft survival, but strong correlation with vasculitis.

The patterns of induced major histocompatibility antigen expression on indigenous cellular elements of heterotopic rat cardiac grafts were determined by immunohistologic methods in a variety of donor-recipient combinations. Heart grafts were studied in combined full-MHC- and non-MHC-disparate combinations, isolated intra-MHC-disparate combinations, and non-MHC-disparate combinations. The pattern of class II expression on cellular constituents of the grafts was highly variable and critically dependent upon the nature of the specific unidirectional donor-recipient combination. No uniform pattern of class II expression emerged that was clearly predictive of rapidity of rejection or of protracted survival. However, vasculitis was confined to grafts in combinations in which induced class II expression on graft large vessel endothelium was present. Sites of vasculitis were never encountered in the absence of induced class II expression on overlying endothelium. Vasculitis and associated induced class II expression on large vessel endothelium were present in rapidly rejecting grafts and in grafts with indefinite survival. In the latter, vasculitis was shown to progress to a late phase of occlusive intimal thickening. Induced class I expression on graft cardiac myofibers was present in all the genetically disparate donor-recipient combinations examined in this study, irrespective of the length of graft survival. This investigation has shown that no uniform stereotyped pattern of MHC antigen expression on cellular constituents correlates with the length of graft survival. However, induced class II expression on graft large vessel endothelium is closely associated with vasculitis, which can directly progress to occlusive intimal thickening in grafts with prolonged survival.

The effects of genetics and age on expression of MHC class II and CD4 antigens on rat cardiac interstitial dendritic cells.

Interstitial dendritic cells (IDC) in normal hearts of inbred rat strains and congenic and congenic recombinant lines were identified and quantitated by immunohistologic methods, on the basis of cellular reactivity with MRC-OX6, a monoclonal antibody (MAb) directed against MHC class II determinants, and with W3/25, a MAb directed against a CD4 epitope. In all strains and lines examined, the W3/25+ IDC frequency was uniformly high with little interstrain variation. In contrast, all rat strains and lines examined showed either high or low OX6+ IDC frequency. Double staining by two color immunofluorescence indicated that strains with a low OX6+ IDC frequency were characterized by a high frequency of W3/25+ OX6- IDC and a low frequency of W3/25+ OX6+ IDC. In strains with high OX6+ IDC frequency, the majority of IDC coexpressed both markers. Comparative analysis of (i) MHC identical background disparate strains and lines, (ii) MHC disparate background identical strains and lines, and (iii) F2 segregation analysis of intercrosses and backcrosses derived from an original cross between high and low frequency OX6+ IDC strains, all indicated that OX6+ IDC frequency is dependent upon both MHC- and non-MHC-linked genetic factors. It is suggested that rat cardiac OX6+ IDC frequency is influenced by a minimum of two autosomal genes, one of which is MHC linked. The frequencies of both W3/25+ IDC frequency reached adult levels by 10 days of age; adult levels of OX6+ IDC were not attained until Day 21. It is postulated that in the rat heart, W3/25+ OX6- IDC are potential precursors of W3/25+ OX6+ IDC, and that the cellular frequency of coexpression in the adult is under genetic influence. Whether these genetic factors modify constitutive or physiologic levels of class II-inducing lymphokine activity, or influence cellular susceptibility of IDC to induced class II expression is unclear.

Morphologic studies of acute rat cardiac allograft rejection across an isolated major histocompatibility complex class I (RT1A) disparity.

To define the morphologic correlates of acute rat cardiac allograft rejection across an isolated major histocompatibility complex (MHC) class I disparity, rejecting PVG.R1 cardiac allografts transplanted to (PVG x WF)F1 recipients were studied from days 4-8 posttransplantation. Documented ultrastructural tracer techniques as well as immunohistologic and immunoelectron microscopic methods were employed for morphologic analysis. Using intravenously administered horseradish peroxidase as a tracer probe for cell membrane permeability dysfunction, it was shown that severe diffuse loss of integrity of the microvascular endothelium preceded functional rejection, providing strong evidence that the allograft microcirculation is a central target of graft destruction. Also, rejection was associated with localized cardiac myofiber alterations prior to development of significant endothelial changes, indicating that cardiac muscle cells are additional cellular targets of immunologic injury. The ultrastructural features of progressive endothelial and myofiber injury, the predominance of MRC OX8+ lymphocytes and MRC OX6+ macrophages sequestered within the grafts, and the pattern of donor class I expression by allograft endothelium and cardiac myofibers were similar to those observed in rejecting allografts in full MHC-disparate combinations. Since it has been previously shown that MRC OX8+ class I-reactive T cells are absolutely required for rejection in this isolated class I-disparate model, the morphologic data raise the possibility that the OX8+ T lymphocyte subpopulation may also play a highly significant role in rat cardiac allograft rejection across a full MHC disparity.

Dendritic cell-lymphoid cell aggregation and major histocompatibility antigen expression during rat cardiac allograft rejection.

To determine the pattern of cellular expression of donor MHC class I and class II antigens during the course of rat cardiac allograft rejection, ACI cardiac allografts transplanted to BN recipients were examined from day 2 to day 6 using immunohistologic and immunoelectron microscopic methods. We used both monomorphic and donor-specific mouse anti-rat MHC class I and class II mAbs in this study. In normal ACI hearts, MHC class I reactivity was confined to the vascular endothelium and to interstitial cells. Ongoing rejection was characterized by an increased donor MHC class I staining intensity of microvascular endothelium and induction of donor class I surface reactivity on cardiac myofibers. Donor MHC class II reactivity was exclusively confined to interstitial dendritic cells (IDC) in both normal ACI hearts and in rejecting allografts, although rejection was associated with marked fluctuations in class II IDC frequency. An early numerical depression in class II IDC present in both allografts and syngeneic heart grafts was attributed to a direct effect of the transplantation procedure. By days 3-4, allografts showed an absolute overall increase in donor class II IDC frequency, which was associated with the presence of multiple localized high-density IDC-lymphocyte aggregates. The lymphocytes present in the focal areas were predominantly of the class II-reactive Th cell subpopulation. These aggregates may thus represent the in vivo homologue of dendritic cell-lymphocyte clustering, which has been shown to be required for primary class II allosensitization in the rat and mouse in vitro. During the late phase of rejection, there was a marked numerical fall in donor class II IDC, which correlated with extensive overall graft destruction. This study has shown that acute rat cardiac allograft rejection can occur in the absence of donor MHC class II expression by allograft vascular endothelium and cardiac myofibers. The IDC, which are believed to represent the principal class II alloantigen presenting cells in the rat heart, remain the sole class II-expressing cellular constituents of the graft throughout the course of rejection.

Syrian hamsters express two monomorphic class I major histocompatibility complex molecules.

The description of the Syrian hamster major histocompatibility complex (MHC), Hm-1, has progressed to the point that multiple class II alloantigens have been defined using structural and functional studies. However, no comparable success has been achieved using allotypic differences to detect class I molecules. We now report that xenoantisera raised in other species against hamster tissues have made it possible to describe class I MHC homologues in the hamster. Evidence which confirms that these molecules exist includes (1) on immunoprecipitation of radiolabeled lymphoid cell lysates, heterodimers of approximate molecular weight 47 000 and 12 000 are identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), the latter representing hamster beta 2-microglobulin; (2) by direct immunoprecipitation these molecules are ubiquitously expressed on hamster tissues; (3) partial N-terminal amino acid sequence analysis reveals striking homology with class I molecules described in other species. In addition, the amino acid sequence data reveal that two class I molecules are expressed on the surfaces of hamster cells. On two-dimensional PAGE analysis, these molecules are invariant among the several strains of genetically disparate hamsters available for study. We conclude that (1) hamsters have the capacity to make class I MHC molecules, (2) at least two genetic loci are dedicated to this purpose, and (3) no allelic forms can be detected, suggesting that there is no class I polymorphism.