Chitosan as a MAMP,searching for a PRR

Chitosan, a deacetylated chitin derivative, behaves like a general elicitor, inducing a non-host resistance and priming a systemic acquired immunity. The defence responses elicited by chitosan include rising of cytosolic H⁺ and Ca²⁺, activation of MAP-kinases, callose apposition, oxidative burst, hypersensitive response (HR), synthesis of abscissic acid (ABA), jasmonate, phytoalexins and pathogenesis related (PR) proteins. Putative receptors for chitosan are a chitosan-binding protein, recently isolated, and possibly the chitin elicitor-binding protein (CEBiP). Nevertheless, it must be pointed out that biological activity of chitosan, besides the plant model, strictly depends on its physicochemical properties (deacetylation degree, molecular weight and viscosity), and that there is a threshold for chitosan concentration able to switch the induction of a cell death programme into necrotic cell death (cytotoxicity).Key words: chitosan, induced resistance, MAMP, PAMP, PCD, PRR, SARRecognition of microbe-associated molecular patterns (MAMPs), by pattern recognition receptors (PRRs), represents the major trait of innate immunity common to plants and animals. In plant immunity, MAMPs, more commonly known as general elicitors, include lipopolysaccharides (LPS), peptidoglycans, flagellin and fungal cell wall fragments (chitin/chitosan oligomers), phospholipids, oxylipins, fatty acids, sterols, proteins, double stranded RNA and methylated DNA, able to elicit a host defence response by binding to specific PRRs. In this view, chitosan, a deacetylated chitin derivative, behaves like a general elicitor, inducing a non-host resistance, by a PRR-mediated recognition, and priming a systemic acquired immunity (or systemic acquired resistance, SAR).¹ The defence responses elicited by chitosan include: raising of cytosolic Ca²⁺, activation of MAP-kinases, callose apposition, oxidative burst, hypersensitive response (HR), synthesis of abscissic acid (ABA), jasmonate, phytoalexins and pathogenesis related proteins (PR) (Fig. 1 and 2^–20Open in a separate windowFigure 1Different responses induced on Phaseolus vulgaris leaves by treatment with solutions of chitosan with 85% deacetylation degree and different molecular weights; all solutions have been prepared at 0.15% w/v in 0.05 M acetic acid and adjusted at pH 5.6. Callose detection with aniline blue (A–C) 12 h after treatment shows that 76 kD-chitosan elicits the formation of a network of small bright yellow fluorescent spots (B) due to callose apposition between the plasmalemma and the cell wall of some mesophyll cells (see the enlargement in the inset), while 6 kD-chitosan induces lesions involving numerous cells fluorescing in yellow-orange, possibly as consequence of the overlap of phenolics autofluorescence and callose fluorescence (see the enlargement in the inset). In 322 kD chitosan-treated leaves numerous green-fluorescent patches (C), due to chitosan deposits, are present on the leaf epidermis along cell walls, but rarely callose apposition is present. Detection of H₂O₂ deposits (as brownish precipitates in D–F) with 3-3′-diaminobenzydine (DAB), 24 h after 6 kD-chitosan treatment, indicates that the lesions in (A) are constituted by necrotizing cells as a consequence of extensive H₂O₂ deposition (D). At the same time, leaves treated with 76 kD-chitosan show moderate H₂O₂ deposits limited to the same mesophyll cells involved in callose apposition, and often localized around the substomatal cavity into which chitosan can permeate (E, arrow). No H₂O₂ deposition is present in 322 kD-chitosan treated plants (F). Evans blue staining to detect dead cells (stained in blue) 24 h after treatment (G–I) shows that the lesions in (A) have already evolved in extensive necrotic cell death, while only some of the cells with callose deposition visible in (B) had turned to programmed cell death (H) (as previously shown with other techniques). No dead cells are present in leaves treated with 322 kD-chitosan (I).

Table 1

Defence responses elicited by chitosan

Fucophlorethol C,a phlorotannin as a lipoxygenase inhibitor

Fucophlorethol C, a phlorotannin, was isolated from the brown alga Colpomenia bullosa (Scyto-siphonaceae) as a novel lipoxygenase (LOX) inhibitor. It was obtained as a free form from natural origin for the first time. The compound inhibited a soybean LOX to the same extent as the known inhibitor nordihydroguaiaretic acid.     

The woodchuck, Marmota monax, as a laboratory animal

The woodchuck or groundhog (Marmota monax) has been used as a biomedical model for studies of obesity and energy balance, endocrine and metabolic function, central nervous system control mechanisms and cardiovascular, cerebrovascular and neoplastic disease. Methods of care of a woodchuck colony, techniques for handling, restraint, anesthesia, blood sampling and breeding were developed.     

C型凝集素LSECtin识别细菌的研究

目的:通过sLSECtin-Fc蛋白与细菌及细胞的黏附,寻找能与LSECtin结合的细菌。方法:通过ELISA检测sLSECtin-Fc与细菌的黏附,同时构建CHO-pDsRed1-N1-LSECtin稳定细胞株进行与细菌的黏附实验,荧光显微镜进行镜鉴拍照。结果:获得能够与sLSECtin-Fc蛋白黏附的细菌,并且通过过表达LSECtin的稳定株与细菌的黏附,发现LSECtin可以结合大肠杆菌和肺炎链球菌,而不能结合金黄色葡萄球菌和肺炎克雷伯杆菌。结论:发现LSECtin可以结合细菌,为进一步研究LSECtin在先天免疫中的作用奠定了基础。     

Perfringolysin O, a cholesterol-binding cytolysin, as a probe for lipid rafts

Gaining an understanding of the structural and functional roles of cholesterol in membrane lipid rafts is a critical issue in studies on cellular signaling and because of the possible involvement of lipid rafts in various diseases. We have focused on the potential of perfringolysin O (theta-toxin), a cholesterol-binding cytolysin produced by Clostridium perfringens, as a probe for studies on membrane cholesterol. We prepared a protease-nicked and biotinylated derivative of perfringolysin O (BCtheta) that binds selectively to cholesterol in cholesterol-rich microdomains of cell membranes without causing membrane lesions. Since the domains fulfill the criteria of lipid rafts, BCtheta can be used to detect cholesterol-rich lipid rafts. This is in marked contrast to filipin, another cholesterol-binding reagent, which binds indiscriminately to cell cholesterol. Using BCtheta, we are now searching for molecules that localize specifically in cholesterol-rich lipid rafts. Recently, we demonstrated that the C-terminal domain of perfringolysin O, domain 4 (D4), possesses the same binding characteristics as BCtheta. BIAcore analysis showed that D4 binds specifically to cholesterol with the same binding affinity as the full-size toxin. Cell-bound D4 is recovered predominantly from detergent-insoluble, low-density membrane fractions where raft markers, such as cholesterol, flotillin and Src family kinases, are enriched, indicating that D4 also binds selectively to lipid rafts. Furthermore, a green fluorescent protein-D4 fusion protein (GFP-D4) was revealed to be useful for real-time monitoring of cholesterol in lipid rafts in the plasma membrane. In addition, the expression of GFP-D4 in the cytoplasm might allow the investigations of intracellular trafficking of lipid rafts. The simultaneous visualization of lipid rafts in plasma membranes and inside cells might help in gaining a total understanding of the dynamic behavior of lipid rafts.     

Identification of a wheat allergen,Tri a Bd 36K,as a peroxidase

A 36-kDa allergen, Tri a Bd 36K, was purified from wheat albumin and characterized. The protein was similar to barley peroxidase BP-1 both in its amino acid sequence and peroxidase activity. The enzyme seemed to contain L-fucose and D-mannose and the glycan moiety reacted with IgE antibodies in a patient's serum.     

VDAC, a multi-functional mitochondrial protein as a pharmacological target

Regulation of mitochondrial physiology requires an efficient exchange of molecules between mitochondria and the cytoplasm via the outer mitochondrial membrane (OMM). The voltage-dependent anion channel (VDAC) lies in the OMM and forms a common pathway for the exchange of metabolites between the mitochondria and the cytosol, thus playing a crucial role in the regulation of metabolic and energetic functions of mitochondria. VDAC is also recognized to function in mitochondria-mediated apoptosis and in apoptosis regulation via interaction with anti-apoptotic proteins, namely members of Bcl-2 family, and the pro-survival protein, hexokinase, overexpressed in many cancer types. Thus, VDAC appears to be a convergence point for a variety of cell survival and cell death signals, mediated by its association with various ligands and proteins. In this article, we review mammalian VDAC, specifically focusing on VDAC1, addressing its functions in cell life and the regulation of apoptosis and its involvement in several diseases. Additionally, we provide insight into the potential of VDAC1 as a rational target for novel therapeutics.     

Triolein,as a Phagostimulant for Albino Rat

Protaminobacter ruber, having a firm cell wall, could be lyzed by treatment with glycine or penicillin. Among amino acids tested, only glycine showed an excellent effect for the lysis. The optimal amount and time of addition of glycine for the lysis were 6 mg per ml culture and 4 to 5 hr after initiation of the cultivation, respectively. Aeration was necessary for the lysis as well as the growth of P. ruber. Morphological changes during the lysis of the bacterium were confirmed by electron microscopy. Proteins and (δ-ALA dehydratase were excreted into the medium with the progress of lysis.     

Adenovirus Dodecahedron,as a Drug Delivery Vector

Background

Bleomycin (BLM) is an anticancer antibiotic used in many cancer regimens. Its utility is limited by systemic toxicity and dose-dependent pneumonitis able to progress to lung fibrosis. The latter can affect up to nearly 50% of the total patient population, out of which 3% will die. We propose to improve BLM delivery by tethering it to an efficient delivery vector. Adenovirus (Ad) dodecahedron base (DB) is a particulate vector composed of 12 copies of a pentameric viral protein responsible for virus penetration. The vector efficiently penetrates the plasma membrane, is liberated in the cytoplasm and has a propensity to concentrate around the nucleus; up to 300000 particles can be observed in one cell in vitro.

Principal Findings

Dodecahedron (Dd) structure is preserved at up to about 50°C at pH 7–8 and during dialysis, freezing and drying in the speed-vac in the presence of 150 mM ammonium sulfate, as well as during lyophilization in the presence of cryoprotectants. The vector is also stable in human serum for 2 h at 37°C. We prepared a Dd-BLM conjugate which upon penetration induced death of transformed cells. Similarly to free bleomycin, Dd-BLM caused dsDNA breaks. Significantly, effective cytotoxic concentration of BLM delivered with Dd was 100 times lower than that of free bleomycin.

Conclusions/Significance

Stability studies show that Dds can be conveniently stored and transported, and can potentially be used for therapeutic purposes under various climates. Successful BLM delivery by Ad Dds demonstrates that the use of virus like particle (VLP) results in significantly improved drug bioavailability. These experiments open new vistas for delivery of non-permeant labile drugs.     

The potential of a jumping spider, Phidippus clarus, as a biocontrol agent

Spiders, particularly assemblages of species, have been shown to be effective in reducing pest insects and crop damage in field crops and orchards. We investigated the potential for a single jumping spider species to reduce pests in a greenhouse setting. We placed three treatments in large enclosures: 1) control treatment of only sweet basil, Ocimum basilicum L.; 2) sweet basil and a phytophagous pest, fourlined plant bug, Poecilocapsus lineatus (F.) (Heteroptera: Miridae); and 3) sweet basil, fourlined plant bug, and jumping spider Phidippus clarus (Keyserling 1884). After 1 wk, jumping spiders reduced the number of plant bugs. Plants exposed to plant bugs alone were significantly shorter than either control plants or plants exposed to plant bugs and spiders. Chlorophyll concentration did not significantly differ across treatments. We discuss the feasibility of using P. clarus and similar salticids in biocontrol.