Mouse strains with typical mammalian levels of complement activity

Antibody-mediated phagocytosis of the amyloid beta-peptide in microglia is differentially modulated by C1q

Microglial ingestion of the amyloid beta-peptide (Abeta) has been viewed as a therapeutic target in Alzheimer's disease, in that approaches that enhance clearance of Abeta relative to its production are predicted to result in decreased senile plaque formation, a proposed contributor to neuropathology. In vitro, scavenger receptors mediate ingestion of fibrillar Abeta (fAbeta) by microglia. However, the finding that cerebral amyloid deposition in a transgenic mouse model of Alzheimer's disease was diminished by inoculation with synthetic Abeta has suggested a possible therapeutic role for anti-Abeta Ab-mediated phagocytosis. Microglia also express C1qR(P), a receptor for complement protein C1q, ligation of which in vitro enhances phagocytosis of immune complexes formed with IgG levels below that required for optimal FcR-mediated phagocytosis. The data presented here demonstrate FcR-dependent ingestion of Abeta-anti-Abeta complexes (IgG-fAbeta) by microglia that is a function of the amount of Ab used to form immune complexes. In addition, C1q incorporated into IgG-fAbeta enhanced microglial uptake of these complexes when they contained suboptimal levels of anti-Abeta Ab. Mannose binding lectin and lung surfactant protein A, other ligands of C1qR(P), also enhanced ingestion of suboptimally opsonized IgG-fAbeta, whereas control proteins did not. Our data suggest that C1qR(P)-mediated events may promote efficient ingestion of Abeta at low Ab titers, and this may be beneficial in paradigms that seek to clear amyloid via FcR-mediated mechanisms by minimizing the potential for destructive Ab-induced complement-mediated processes.

Inflammatory responses to amyloidosis in a transgenic mouse model of Alzheimer's disease

Mutations in the amyloid precursor protein (APP) and presenilin-1 and -2 genes (PS-1, -2) cause Alzheimer's disease (AD). Mice carrying both mutant genes (PS/APP) develop AD-like deposits composed of beta-amyloid (Abeta) at an early age. In this study, we have examined how Abeta deposition is associated with immune responses. Both fibrillar and nonfibrillar Abeta (diffuse) deposits were visible in the frontal cortex by 3 months, and the amyloid load increased dramatically with age. The number of fibrillar Abeta deposits increased up to the oldest age studied (2.5 years old), whereas there were less marked changes in the number of diffuse deposits in mice over 1 year old. Activated microglia and astrocytes increased synchronously with amyloid burden and were, in general, closely associated with deposits. Cyclooxygenase-2, an inflammatory response molecule involved in the prostaglandin pathway, was up-regulated in astrocytes associated with some fibrillar deposits. Complement component 1q, an immune response component, strongly colocalized with fibrillar Abeta, but was also up-regulated in some plaque-associated microglia. These results show: i) an increasing proportion of amyloid is composed of fibrillar Abeta in the aging PS/APP mouse brain; ii) microglia and astrocytes are activated by both fibrillar and diffuse Abeta; and iii) cyclooxygenase-2 and complement component 1q levels increase in response to the formation of fibrillar Abeta in PS/APP mice.

Organ transplantation in mice: current status and future prospects

With the development of microsurgery and molecular biology in the 1990s, the mouse model for organ transplants has become increasingly popular. In the past 10 years, the number of studies using the mouse model has increased three-fold. All the organ transplants, originally done in the rat model, can now be performed in mice with high success rates. This article reviews the development, advantages, limitations, and unique immunology of the mouse model as well as future prospects.

Spontaneous combined hyperlipidemia, coronary heart disease and decreased survival in Dahl salt-sensitive hypertensive rats transgenic for human cholesteryl ester transfer protein

The acceleration of atherosclerosis by polygenic (essential) hypertension is well-characterized in humans; however, the lack of an animal model that simulates human disease hinders the elucidation of pathogenic mechanisms. We report here a transgenic atherosclerosis-polygenic hypertension model in Dahl salt-sensitive hypertensive rats that overexpress the human cholesteryl ester transfer protein (Tg[hCETP]DS). Male Tg[hCETP]DS rats fed regular rat chow showed age-dependent severe combined hyperlipidemia, atherosclerotic lesions, myocardial infarctions and decreased survival. These findings differ from various mouse atherosclerosis models, demonstrating the necessity of complex disease modeling in different species. The data demonstrate that cholesteryl ester transfer protein can be proatherogenic. The interaction of polygenic hypertension and hyperlipidemia in the pathogenesis of atherosclerosis in Tg[hCETP]DS rats substantiates epidemiological observations in humans.

The mouse C1q A-chain sequence alters beta-amyloid-induced complement activation

In transgenic models of Alzheimer's disease (AD) neuronal loss has not been widely observed. The loss of neurons in AD may be due to chronic activation of complement (C') by beta-amyloid (A beta). A beta has been shown to activate C' by binding to a site on the C1q A-chain. The mouse A-chain sequence differs significantly from human, and a peptide based on the mouse A-chain sequence was ineffective at blocking activation of C' by A beta in contrast to the inhibition seen with the human peptide. Comparison of mouse and human serum showed that human C' was activated more effectively by A beta than was mouse C'. Therefore, additional genetic manipulations may be necessary to replicate in the murine model the inflammation and neurodegeneration that occur in AD.

Hippocampal neuron and synaptophysin-positive bouton number in aging C57BL/6 mice

A loss of hippocampal neurons and synapses had been considered a hallmark of normal aging and, furthermore, to be a substrate of age-related learning and memory deficits. Recent stereological studies in humans have shown that only a relatively minor neuron loss occurs with aging and that this loss is restricted to specific brain regions, including hippocampal subregions. Here, we investigate these age-related changes in C57BL/6J mice, one of the most commonly used laboratory mouse strains. Twenty-five mice (groups at 2, 14, and 28-31 months of age) were assessed for Morris water-maze performance, and modern stereological techniques were used to estimate total neuron and synaptophysin-positive bouton number in hippocampal subregions at the light microscopic level. Results revealed that performance in the water maze was largely maintained with aging. No age-related decline was observed in number of dentate gyrus granule cells or CA1 pyramidal cells. In addition, no age-related change in number of synaptophysin-positive boutons was observed in the molecular layer of the dentate gyrus or CA1 region of hippocampus. We observed a significant correlation between dentate gyrus synaptophysin-positive bouton number and water-maze performance. These results demonstrate that C57BL/6J mice do not exhibit major age-related deficits in spatial learning or hippocampal structure, providing a baseline for further study of mouse brain aging.

Genetic linkage analysis of collagen-induced arthritis in the mouse

The genetic susceptibility to collagen-induced arthritis (CIA) in mice, the most commonly used model for rheumatoid arthritis, has been analyzed. The highly susceptible B10.RIII strain was crossed with the resistant RIIIS/J strain and the F2 intercross mice were subjected to genomic screening using microsatellite markers. These strains share the MHC region on chromosome 17, known to be of importance in CIA (this locus is named Mcia1). The same cross has earlier been used to map the major genes outside the MHC controlling chronic relapsing experimental allergic encephalomyelitis (EAE). It was found that the major locus controlling CIA (Mcia2; lod 4.12) was located on chromosome 3 in the same region as one of the major loci controlling EAE (Eae3). The linkage was reproduced in a mouse strain in which the locus was isolated on the B10.RIII background at the N4I2 generation. A second putative locus was identified on chromosome 13 (lod 3.13). The present finding identifies new loci outside the MHC controlling CIA and provides evidence that mouse CIA is controlled by polymorphic genes.

The hemolytic and complement-activating properties of pneumolysin do not contribute individually to virulence in a pneumococcal bacteremia model

The virulence of pneumococcal capsular type 2 strain D39 and derivatives with mutations in the pneumolysin gene were examined in a mouse bacteremia model. In CBA/N-XID mice D39 is known to exhibit exponential growth in the blood until the death of the mice at 24 to 36 h. In contrast, PLN, a pneumolysin-deficient derivative of D39, reaches a plateau in growth that is maintained for several days. The growth patterns of D39 and PLN observed in CBA/N-XID mice were also observed in C3H/HeJ and C3H/HeOuJ mice, but not in 129/SvJ and C57BL/6J mice. These results demonstrate that the effect of pneumolysin on bacteremia is dependent on the genetic background of the mice. D39 derivatives with point mutations which abolish the cytotoxic or complement-activating properties of pneumolysin did not have major individual effects on virulence in CBA/N- XID and C3H/HeOuJ mice. A derivative with mutations affecting both the cytotoxic and complement- activating properties resulted in a modest, yet statistically significant, increase in survival time of i.v. challenged CBA/N-XID mice. However, the effect was less marked than that seen with PLN. These findings suggest that the virulence effects of pneumolysin in bacteremia must be due in part to properties other than hemolysis and complement fixation.

Targeting of antihapten antibodies to activated T cells via an IL-2-hapten conjugate prolongs cardiac graft survival

Antihapten antibodies binding to ligand-hapten conjugates are able to mediate complement mediated lysis in vitro. Based on this observation we propose a new in vivo immunotherapy using molecules that combine a low molecular weight hapten binding to antibodies preexisting in serum and a cell specific ligand. The ligand-hapten conjugates are potential cytotoxic drugs which may (1) be specific for a given target cell, (2) be nonimmunogenic, (3) be of low molecular weight, (4) form soluble complexes with preexisting antibodies resulting in prolonged half life of the drug, and (5) induce a potent antibody mediated rejection of target cells. These novel compounds could be useful for the elimination of certain cell subsets involved in allograft rejection, cancers, infectious diseases, etc., without some of the pitfalls of conventional immunotherapies. The feasibility of this approach was demonstrated in an animal model using a compound consisting of one interleukin 2 and one fluorescein molecule (IL-2-FITC). BALB/c mice (H2d) previously immunized and expressing anti-FITC antibodies were transplanted with a fully mismatched C57BL/6 (H2b) heterotopic heart allograft. Untreated controls rejected their graft by day 9 (MSD = 9 +/- 0.7). Mice with preexisting anti-FITC antibodies treated with IL-2-FITC maintained their grafts for 38.7 +/- 7.1 days (P < 0.02). No prolongation of graft survival was observed in immunized animals that were treated with IL-2 alone (MSD = 10 +/- 1.4). Nonimmunized animals treated with IL-2-FITC rejected their grafts on day 9.4 +/- 1.1. This demonstrates that IL-2-FITC therapy specifically prolonged graft survival in animals with circulating anti-FITC antibodies. The data suggest that a ligand/hapten pair can redirect preexisting antihapten antibodies toward target cells in vivo. Such compounds may be developed for human use as alternatives to polyclonal or monoclonal antibody therapy.

Systemic autoimmunity in LG/J mice

Humoral and end-organ parameters of autoimmunity were investigated in LG/J mice, which have traditionally been considered normal, non-diseased animals. Surprisingly, LG/J mice were found to possess autoantibodies, including antinuclear antibodies and rheumatoid factor, and to develop renal disease, including glomerulonephritis, interstitial nephritis, and perivasculitis, but not hepatic or cutaneous disease. In contrast, age-matched, identically-housed control animals failed to develop autoantibodies or end-organ disease. These findings have complications for the genetic study of lupus erythematosus in the MRL murine model, which derives heavily from the LG/J background. Thus, the LG/J strain may provide a useful model in the analysis of autoimmunity.

Rabbit complement lyses tumor cells without massive C3 deposition

These experiments were performed to determine why rabbit complement lyses tumor cells very efficiently, while not having particularly strong activity in hemolytic assays or in any other complement assay. The target cells used were human tumor cells coated with three different mouse IgG(2a) monoclonal antibodies, and complement from 5 mammalian species were tested. In antibody titration experiments, rabbit complement was found to lyse target cells at a relatively low antibody concentration, insufficient to allow lysis by complement of other species. Since this result was still observed after absorption of rabbit serum with target cells, the potency of rabbit complement cannot be attributed to the presence of natural antibodies. We then assayed C3 deposition on target cells, using two types of (125)I-labeled anti-C3 Abs to measure C3 deposition: goat antibodies specific for C3 of the human, guinea pig, rabbit, rat or mouse, and chicken antibodies to human C3 which cross-react with C3 of other mammals. Unexpectedly, complement of the human, rat, guinea pig, and BUB mouse deposited large amounts of C3 on the surface of target cells, while rabbit complement deposited 100-1,000 fold less. We discuss the possible reasons that C3 deposition does not correlate with cytotoxicity, and may indeed be inversely related. These data indicate that there is a fundamental difference in the complement cascade between rabbits and the other species tested. The potent lytic activity of rabbit complement is likely to be related to this difference, although the mechanism is not yet understood.

The specificity of alternative complement pathway-mediated lysis of erythrocytes: a survey of complement and target cells from 25 species

Sera from 20 species of mammals were tested for their ability to lyse erythrocytes from 18 species of mammals and birds by the alternative complement pathway. Erythrocytes were not lysed by homologous complement, with one minor exception, but all erythrocytes tested were lysed by at least one complement source, and all sera tested except that of the horse lysed at least one type of erythrocyte. Control experiments indicated that lysis was via the alternative complement pathway and that antibodies were not involved. Complement from the various species could be ranked from most active to least active, and erythrocytes could be ranked from most susceptible to least susceptible. There was an inverse correlation between complement activity and erythrocyte susceptibility. The ranking of the orders of placental mammals, from strongest to weakest complement, was carnivore > artiodactyl (ruminants and swine) > primate = armadillo > rodent > rabbit > horse. Opossum serum had activity that placed it in the centre of this range. Ferret complement, the most potent tested, lysed all erythrocytes tested except for homologous erythrocytes, with APCH50 titres as high as 4000. Although the overall reactivity pattern was clear, there were several striking exceptions. For example, the only complement source which lysed ferret erythrocytes was sera of the mouse. The amount of sialic acid present on erythrocytes of 14 mammals was determined, and was, in general, directly correlated with resistance to alternative complement pathway lysis, although there were prominent exceptions to this correlation, involving erythrocytes of the horse, burro and human. All 20 types of complement were also tested for their ability to lyse antibody-coated human tumour cells, under conditions in which both the classical and alternative complement pathways were functional. The data obtained suggest that alternative pathway activation is, in some cases, a major factor determining the effectiveness of a particular complement source in the lysis of xenogeneic tumour cells.

Analysis of high complement levels in Mus hortulanus and BUB mice

BUB/BnJ mice were previously identified as having exceptionally potent complement activity, relative to common mouse strains, in the lysis of antibody-coated human tumor cells. We describe herein our investigation into the molecular and genetic basis for this difference between mouse strains, and also our results with wild mice and mouse strains recently derived from the wild, to determine whether low complement levels are characteristic of wild mice. BUB complement was compared with complement from BALB/c and C57BL/6 mice. BUB mice had higher levels of most individual classical pathway components, except for C1, than the other two strains, but the difference was generally only 2-3-fold, so insufficient to fully explain the difference observed with tumor target cells. CH50 titers on antibody-coated sheep erythrocytes also demonstrated only a 2-4-fold difference. However, CH50 titers on antibody-coated human erythrocyte target cells demonstrated a difference similar in magnitude to that seen with human tumor targets. These results suggest that the difference between mouse strains depends partly on the use of human, rather than sheep, target cells. In an assay for alternative complement pathway activity using neuraminidase-treated human erythrocytes as targets, complements of BALB/c and BUB mice were similar in activity, suggesting that the difference between mouse strains is manifested in the early steps of complement activation. Analysis of F1 and backcross mice suggested that the difference in complement level between BUB and BALB/c or C57BL/6 mice is controlled by semi-dominant genes, and cannot be attributed to a single gene. Wild mice and mice recently derived from the wild generally had low complement levels, similar to most laboratory mice. However, three strains of aboriginal mice, including Mus hortulanus (spicilegus) and Mus spretus, had complement levels higher than that of BUB mice, and as high as sera from the rabbit or rat, which are the most potent known complement sources for the lysis of human tumor cells. In comparison with BUB mouse sera, M. hortulanus sera had at least four-fold higher levels of C3, C6, C8 and C9, and some or all of these differences may explain its higher total complement activity. In the lysis of antibody-coated human erythrocytes, M. hortulanus serum was more potent than any other complement source tested, including sera of the guinea pig, rat, rabbit or human. These strains may be useful in investigating the role of complement in various pathological processes, and in investigating the genetic regulation of the complement system.

B cell tolerance in mice transgenic for anti-CD8 immunoglobulin mu chain

To analyze in vivo the induction of B cell tolerance against a T cell surface antigen, we generated transgenic mice expressing an anti-CD8.2 mu heavy chain gene. We show that self-specific B cells are efficiently tolerized if they express the membrane-bound form of the transgenic mu chain on their surface but that they can escape tolerization if they express only the secreted form. In the latter, we find an enhanced expression of anti-CD8.2 antibodies after polyclonal B cell activation. As a result, transgenic anti-CD8.2 antibodies bind to the CD8+ T cells but they did not induce their elimination. Furthermore, we observed the preferential expression of a limited subset of endogenous light chains with the transgenic mu chain. This suggests a positive or negative selection for particular heavy and light chain combinations in B lymphocytes.