Toxicity studies of coumarin 6-encapsulated polystyrene nanospheres conjugated with peanut agglutinin and poly(N-vinylacetamide) as a colonoscopic imaging agent in rats.

We are investigating an imaging agent that detects early-stage primary colorectal cancer on the mucosal surface in real time under colonoscopic observation. The imaging agent, which is named the nanobeacon, is fluorescent nanospheres conjugated with peanut agglutinin and poly(N-vinylacetamide). Its potential use as an imaging tool for colorectal cancer has been thoroughly validated in numerous studies. Here, toxicities of the nanobeacon were assessed in rats. The nanobeacon was prepared according to the synthetic manner which is being established as the Good Manufacturing Practice-guided production. The rat study was performed in accordance with Good Laboratory Practice regulations. No nanobeacon treatment-related toxicity was observed. The no observable adverse effect levels (NOAEL) of the nanobeacon in 7-day consecutive oral administration and single intrarectal administration were estimated to be more than 1000mg/kg/day and 50mg/kg/day, respectively. We concluded that the nanobeacon could be developed as a safe diagnostic agent for colonoscopy applications. FROM THE CLINICAL EDITOR: Colon cancer remains a major cause of death. Early detection can result in early treatment and thus survival. In this article, the authors tested potential systemic toxicity of coumarin 6-encapsulated polystyrene nanospheres conjugated with peanut agglutinin (PNA) and poly(N-vinylacetamide) (PNVA), which had been shown to bind specifically to colonic cancer cells and thus very promising in colonoscopic detection of cancer cells.

Epicutaneous immunization converts subsequent and established antigen-specific T helper type 1 (Th1) to Th2-type responses.

Epicutaneous immunization is a potential novel technique for topical vaccine delivery. It targets the immunologically rich milieu of the skin while having the advantage of being a non-invasive immunization procedure. By disrupting the stratum corneum of the epidermis a natural adjuvant effect can be achieved through activation of resident Langerhans cells. This negates the normal need for co-application of noxious adjuvants. Epicutaneous immunization on barrier-disrupted skin induces potent antigen-specific systemic immunity with a strong T helper type 2 (Th2) bias. We show here that epicutaneous immunization enhances the vigour of a subsequent T-cell response to the same antigen. The induced systemic Th2 response prevents the development of Th1 responses induced through injection of antigen in complete Freund's adjuvant (CFA). Prior epicutaneous immunization results in reduced production of antigen-specific interferon-gamma and immunoglobulin G2a (IgG2a) and enhanced interleukin-4, IgG1 and IgE responses to immunization with CFA. Moreover, epicutaneous immunization converts an established Th1 response to a Th2 response, as demonstrated by the specific reduction of interferon-gamma and IgG2a and the enhancement of interleukin-4 and IgE. This Th2 dominance of epicutaneous immunization may have direct therapeutic application as an immune-modulating procedure in Th1-dominant diseases such as autoimmune rheumatoid arthritis, type 1 diabetes, Hashimoto's thyroiditis and multiple sclerosis.

Intradermal exposure of BALB/c strain mice to peanut protein elicits a type 2 cytokine response.

There is a growing need for the development of methods to characterize the allergenic properties of novel proteins, particularly those expressed by transgenic crop plants. Hence, there is considerable interest in the development of suitable animal models for this purpose. The production of specific IgE antibody has been reported following sensitization with food allergen via oral or systemic (intraperitoneal) routes of exposure. We have characterized cytokine profiles induced by intradermal treatment of BALB/c strain mice with a purified peanut allergen, Arachis hypogea lectin. Mice were exposed to peanut lectin by intradermal administration and the cytokine responses in the lymph node draining the site of exposure analyzed at the secreted protein level by enyzme-linked immunosorbent assay (ELISA) and cytokine mRNA level by ribonuclease protection assay (RPA). Exposure to peanut lectin, under conditions that induced robust IgE antibody titers, was found to be associated with a T helper 2 (Th2)-type cytokine expression profile at both the mRNA and secreted protein levels. Culture of naïve lymph node cells with peanut lectin failed to stimulate marked proliferation or cytokine production, confirming this protein is not mitogenic for mouse lymphocytes. Furthermore, the expression of Th2 cytokines was associated with the effector/memory CD62L- cell population. Similar treatment with a non-allergenic protein, potato acid phosphatase, failed to induce Th2 cytokine expression. These data demonstrate that exposure of mice to peanut allergen results in the selective stimulation of a Th2-type response.

Potential of lectin-N-(2-hydroxypropyl)methacrylamide copolymer-drug conjugates for the treatment of pre-cancerous conditions.

N-(2-Hydroxypropyl)methacrylamide (HPMA)-lectin (wheat germ agglutinin (WGA), peanut agglutinin (PNA)) drug conjugates for treatment of the pre-cancerous conditions ulcerative colitis and Barrett's esophagus are being developed. Cell-surface glycoproteins that are altered in disease and development bind lectins. PNA binds alpha-lactose and the Thomsen-Friedenreich (TF) antigen, a disease- and development-associated glycoprotein. PNA incorporation in conjugates may allow for preferential delivery to diseased over healthy tissues. Conjugates were prepared by attaching lectins to HPMA copolymers via an amide linkage. Frontal affinity chromatography was used to measure dissociation constants (K(d)) of free and conjugated lectins. Animal models of colitis (DSS, TNBS/EtOH) were developed. Human biopsy specimens were obtained. Free and HPMA copolymer-conjugated FITC-labeled lectin and anti-TF antigen antibody binding patterns were examined in normal neonatal, adult and diseased rodent tissues and normal and diseased human tissues. K(d) values of free and conjugated lectins were similar ( approximately 10(-5) M(-1)). Free and conjugated lectins had comparable binding patterns. In health, strong WGA binding was seen in goblet cells; PNA binding was minimal, occurring only in the supranuclear goblet cell region. In disease, WGA binding was not altered, but PNA binding was increased in both human and rodent tissues; entire goblets bound the lectin. Anti-TF antigen antibody binding was minimal, but did overlap with PNA binding patterns both in normal and diseased tissues. Conjugation of lectins to HPMA copolymers does not affect binding affinity. Alterations in glycoprotein structures in development and disease resulted in modified lectin binding patterns. In development and disease, the PNA binding seen was to the TF antigen and other lactose-containing glycoproteins. The results suggest that site-specific delivery of therapeutic agents such as cyclosporin A (CsA) for ulcerative colitis and mesochlorin e(6) for Barrett's esophagus may be achieved. P(HPMA)-lectin-CsA conjugates have been prepared and preliminary in vivo studies are underway.

Systemic effect of peanut agglutinin following intravenous infusion into rats.

BACKGROUND: Ingested peanut agglutinin stimulates colonic proliferation in humans. In rats, ingested peanut agglutinin stimulates hormone release and proliferation in the small and large intestines. Peanut agglutinin is absorbed into the circulation but little is known about the systemic effect of this lectin. Therefore, we studied the effect of intravenous peanut agglutinin on hormone release and intestinal growth. METHOD: Six rats per group received peanut agglutinin infusion at 0, 2, 20 or 200 microg/rat/day for 6 days via the right jugular vein. Organ weights were measured, pancreatic enzymes, DNA, RNA and protein levels were analysed. Plasma hormones were measured by radioimmunoassay. All tissues were examined histologically. Small intestinal and colonic proliferation rates were estimated by metaphase arrest. RESULTS: High-dose peanut agglutinin significantly reduced the wet weight of the stomach by 7% (P < 0.05) and large intestine by 10% (P < 0.05). Peanut agglutinin dose-dependently released enteroglucagon; low-, medium- and high-dose by 64%, 126% (P < 0.01) and 180% (P < 0.01), respectively, and glucagon-like peptide-1 by 127% (P < 0.01), 169% (P < 0.01) and 315% (P < 0.001), respectively. Peanut agglutinin had no effect on cholesystokinin, gastrin or insulin levels. Peanut agglutinin, low-, medium- and high-dose stimulated proliferation in the mid colon by 42% (P < 0.01), 30% and 38%, respectively. Only high-dose peanut agglutinin stimulated proliferation in the distal colon by 54% (P < 0.01). No histological changes were evident in any tissue. CONCLUSION: Intravenous peanut agglutinin released hormones and stimulated colonic proliferation. Proliferation of the small intestine seen after ingestion of peanut agglutinin in previous studies appears to require luminal contact between enterocytes and the lectin. Possible clinical applications include reversal of atrophy during total parenteral nutrition, anastomotic healing after surgery and restoration of mucosa integrity in colitis.