Representational and experimental modeling in archaeology.

I distinguish, by specificity and representational function, several different types of archaeological models: phenomenological, scaffolding, and explanatory models. These take the form of concrete, mathematical, and computational models (following Weisberg’s taxonomy), and they exemplify what Morgan describes as the double life of models; they vary significantly in the degree to which they are intended to accurately represent a particular target, or are media for experimental manipulation of idealized cultural processes. At the phenomenological end of the spectrum, representational models of data include typological constructs that selectively represent variability in archaeological data on several dimensions: formal (material), spatial, and temporal. Archaeologists also build phenomenological models of data drawn from nonarchaeological sources – cultural and natural – that are relevant for interpreting archaeological data as evidence. Assemblages of these target and source models provide the necessary scaffolding for building and evaluating more ambitious explanatory and experimental models of cultural systems and processes, actual and hypothetical

GLOMERULONEPHRITIS INDUCED BY MONOCLONAL ANTI-THY 1.1 ANTIBODIES - A SEQUENTIAL HISTOLOGICAL AND ULTRASTRUCTURAL-STUDY IN THE RAT

The present report describes the natural history of an experimental acute glomerulonephritis with massive proteinuria induced by a single intravenous injection of a (mouse) monoclonal anti-rat Thy 1.1 antibody into the rat. The disease is characterized by direct although transient binding of this monoclonal antibody to glomerular basement membrane and mesangium after injection as demonstrated by immunofluorescence microscopy. Immediate activation of complement occurs as shown by glomerular deposition of C3 and C9. Concomitant activation of the coagulation cascade is reflected by the presence of fibrinogen deposits in the affected glomeruli. One hour after injection mesangial alterations are prominent including condensation of mesangial cell chromatin, and lysis of mesangial cells as shown by light- and electron- microscopy, leading to the formation of aneurysms in the capillary tuft. Commencing on day 4 mesangial cell proliferation can be observed, accompanied by glomerular crescent formation at day 14, which decreases gradually 3 weeks after antibody administration, whereas mesangial hypercellularity can be observed up week 10 after intravenous injection of the antibody. The disease is clinically characterized by a massive transient proteinuria starting immediately after antibody injection, reaching mean values of 300 mg/24 hours at days 2 to 4, gradually decreasing to normal levels after 3 weeks. It is concluded that in this unique model of glomerulonephritis induced by a monoclonal antibody, recognition of Thy 1.1 epitopes as well as activation of complement including the C5-C9 membrane attack complex may play a major role in the pathogenesis of this experimental diseas

THE SPECIFICITY OF NEPHRITOGENIC ANTIBODIES .4. BINDING OF MONOCLONAL ANTITHYMOCYTE ANTIBODIES TO RAT-KIDNEY

Polyclonal rabbit antirat thymocyte serum (ATS) has been shown to form in situ glomerular immune aggregates following perfusion into normal rat kidney ex vivo. This may be due to the presence of T-cell-like epitopes in the rat kidney, or it may be a result of contaminating anti-connective-tissue antibodies in ATS. To exclude the latter possibility we investigated binding to the rat kidney of three different (mouse) monoclonal antirat thymocyte antibodies (anti-T-cell MoAbs), directed to Thy 1.1 antigen, as well as (control) anti-B-cell MoAbs. The MoAbs were incubated in vitro with kidney sections or perfused into the blood-free rat kidney ex vivo. It was shown using immunofluorescence (IF) and immunoelectron microscopy (IEM) (peroxidase technique) that the anti-T-cell MoAbs used, in contrast to anti-B-cell MoAbs, are able to bind with glomerular capillary walls, and with mesangial structures after incubation in vitro or perfusion ex vivo. Although staining patterns are not completely identical, the reaction product is clearly demonstrated throughout the glomerular basement membrane (GBM) and along the plasma membranes of endothelial and epithelial cells, after contact with either of the three anti-T-cell MoAbs used. It is concluded that the presence of T-cell-like epitopes in the rat kidney may lead to immune complex formation following contact with anti-T-cell MoAbs. The nephritogenicity of rabbit ATS, as well as of some batches of clinically used ATS, may also be explained by this mechanism rather than by the usually assumed presence of contaminating antibodies in these polyclonal antiser