Impact of the nature and size of the polymeric backbone on the ability of heterobifunctional ligands to mediate shiga toxin and serum amyloid p component ternary complex formation.

Inhibition of AB(5)-type bacterial toxins can be achieved by heterobifunctional ligands (BAITs) that mediate assembly of supramolecular complexes involving the toxin's pentameric cell membrane-binding subunit and an endogenous protein, serum amyloid P component, of the innate immune system. Effective in vivo protection from Shiga toxin Type 1 (Stx1) is achieved by polymer-bound, heterobifunctional inhibitors-adaptors (PolyBAITs), which exhibit prolonged half-life in circulation and by mediating formation of face-to-face SAP-AB(5) complexes, block receptor recognition sites and redirect toxins to the spleen and liver for degradation. Direct correlation between solid-phase activity and protective dose of PolyBAITs both in the cytotoxicity assay and in vivo indicate that the mechanism of protection from intoxication is inhibition of toxin binding to the host cell membrane. The polymeric scaffold influences the activity not only by clustering active binding fragments but also by sterically interfering with the supramolecular complex assembly. Thus, inhibitors based on N-(2-hydroxypropyl) methacrylamide (HPMA) show significantly lower activity than polyacrylamide-based analogs. The detrimental steric effect can partially be alleviated by extending the length of the spacer, which separates pendant ligand from the backbone, as well as extending the spacer, which spans the distance between binding moieties within each heterobifunctional ligand. Herein we report that polymer size and payload of the active ligand had moderate effects on the inhibitor's activity.

Complement component C1q inhibits beta-amyloid- and serum amyloid P-induced neurotoxicity via caspase- and calpain-independent mechanisms.

Alzheimer's disease is a neurodegenerative disorder characterized by neuronal loss, beta-amyloid (Abeta) plaques, and neurofibrillary tangles. Complement protein C1q has been found associated with fibrillar Abeta deposits, however the exact contributions of C1q to Alzheimer's disease is still unknown. There is evidence that C1q, as an initiator of the inflammatory complement cascade, may accelerate disease progression. However, neuronal C1q synthesis is induced after injury/infection suggesting that it may be a beneficial response to injury. In this study, we report that C1q enhances the viability of neurons in culture and protects neurons against Abeta- and serum amyloid P (SAP)-induced neurotoxicity. Investigation of potential signaling pathways indicates that caspase and calpain are activated by Abeta, but C1q had no effect on either of these pathways. Interestingly, SAP did not induce caspase and calpain activation, suggesting that C1q neuroprotection is in distinct from caspase and calpain pathways. In contrast to Abeta- and SAP-induced neurotoxicity, neurotoxicity induced by etoposide or FCCP was unaffected by the addition of C1q, indicating pathway selectivity for C1q neuroprotection. These data support a neuroprotective role for C1q which should be further investigated to uncover mechanisms which may be therapeutically targeted to slow neurodegeneration via direct inhibition of neuronal loss.

Serum amyloid P component induces TUNEL-positive nuclei in rat brain after intrahippocampal administration.

Serum amyloid P component (SAP)-induced neuronal apoptosis has been demonstrated on the primary culture of embryonic rat cerebral cortex in vitro. Here we present pieces of evidence that cell death is also induced by serum amyloid P component in living rat brain similarly to that in cell culture. Intrahippocampally administered SAP diffuses from the site of injection to the cortical and subcortical area of the rat brain and enters the cells of brain tissue in 1 week. It induces elevation of the number of in situ TdT-mediated dUTP-X nick end-labeled nuclei in the hippocampus, cortex and subcortical structures of rat central nervous system. DNA fragmentation, which is detected by the end labeling reaction, is characteristic to apoptosis. It develops in 4 weeks following exposure. Apoptosis is an important form of cell death in different neurodegenerative diseases including Alzheimer's disease. Our present work reveals that apoptosis can be induced by SAP beyond other hitherto known apoptosis inducing components of neurodegeneration. Hereby SAP seems to be an important component of the process, which leads to expanded neuronal loss in the pathomechanism of neurodegenerative diseases.

Glycosaminoglycans inhibit neurodegenerative effects of serum amyloid P component in vitro.

Serum amyloid P component, a member of pentraxin serum protein family, has been suggested to contribute to the progression of neurodegeneration including Alzheimer's disease by binding to beta-amyloid fibrils leading to an increased stability of the deposits against proteolytic degradation and by inducing neuronal apoptosis. Here, we show that glycosaminoglycans inhibit both the serum amyloid P component-beta-amyloid interaction and the neurotoxic effect of serum amyloid P component. These effects correlate with the structure of glycosaminoglycans and show different structure-activity relationship in the case of the two different effects. While the efficacy of the inhibition on the serum amyloid P component-induced cell death increases with the uronic acid content, the inhibitory activity on the serum amyloid P component-beta-amyloid interaction decreases with the increasing uronic acid content of the glycosaminoglycans. The inhibitory effect of glycosaminoglycans on the interaction between the first component of the complement cascade (C1q) and beta-amyloid shows a similar structure-activity relationship as on the serum amyloid P component-beta-amyloid interaction. This suggests that glycosaminoglycans interfere with the binding site on beta-amyloid for serum amyloid P component and C1q. The functional consequence of this binding has been demonstrated by heparin which promotes the proteolysis of beta-amyloid in vitro in the presence of serum amyloid P component. Our results suggest that glycosaminoglycans might have therapeutical potential on the neurodegeneration reducing its progress.

The in vitro neuronal toxicity of pentraxins associated with Alzheimer's disease brain lesions.

Serum amyloid P component (AP) and C-reactive protein (CRP) are normal serum components which belong to the pentraxin family of proteins. These proteins have been previously localized by immunohistochemical method to the brain lesions of Alzheimer's disease (AD). AP is a constant constituent of amyloid deposits including those found in AD. Both AP and CRP have been localized to AD neurofibrillary tangles. An indirect role for these proteins has been previously suggested in the etiology of AD. We studied the effects of serum AP and CRP on a human-derived neuronal cell line (hNT). In treated cell cultures, AP and CRP were detected immunohistochemically within hNT neurons, indicating cellular uptake of these proteins. Serum AP at the lowest serum physiological concentration (8 microgram/ml) showed a marked toxicity to hNT neurons. CRP also displayed toxicity to the hNT neurons but at a level compatible with inflammatory states (50 microgram/ml). These results suggest a more direct role for serum AP and CRP in the pathogenesis of AD.

Serum amyloid P component-induced cell death in primary cultures of rat cerebral cortex.

The influence of serum amyloid P component (SAP) on the survival of rat cerebrocortical cultures was tested. Cytotoxic cell death was examined on 8-9-day-old cell cultures by phase contrast microscopy and quantified by the measurement of lactate dehydrogenase (LDH) leakage. SAP (16-48 nM) evoked a concentration-dependent cell death within 24 h exposure. Our results suggest that SAP, as a constituent of cerebral amyloid deposits, may play a role in the pathomechanism of Alzheimer's disease.

Imaging of experimental amyloidosis with 131I-labeled serum amyloid P component.

131I-labeled human serum amyloid P component, which was injected into mice with experimentally induced systemic AA amyloidosis and into controls, became specifically localized and was retained in amyloidotic organs. In comparison, it was rapidly and completely eliminated from unaffected tissues and from control animals. Distinctive images of this amyloid-specific deposition of labeled serum amyloid P component were derived from whole body scanning, in vivo, of amyloidotic mice. These findings suggest that such imaging may have applications for the diagnosis and quantitation of amyloid deposits in humans.