Effect of the molecular weight of chitosan on its antiviral activity in plants

The effect of the molecular weight of chitosan on its ability to suppress systemic infection of bean mild mosaic virus in bean (Phaseolus vulgaris L.) plants was studied. The enzymatic hydrolysate of low-molecular-weight chitosan was successively fractionated by ultrafiltration through membranes with decreasing pore size. In total, four chitosan fractions with a weight-average molecular weight varying from 1.2 to 40.4 kDa were obtained. It was shown that the treatments of bean plants with these fractions (chitosan concentration, 10 or 100 μg/ml) inhibited virus accumulation and systemic propagation. The degree of chitosan-induced antiviral resistance increased as the molecular weight of chitosan decreased. The monomers comprising the chitosan molecule—glucosamine and N-acetylglucosamine—exhibited no antiviral activity.     

Identification of the Low Molecular Weight Copper Protein from Copper-intoxicated Mung Bean Plants

Mung bean plants (Wilczek) accumulate increasingly greater amounts of buffer-extractable copper in both their shoots and roots when grown in liquid medium containing greater than 2 micrograms per milliliter copper (31.4 micromolar) as cupric sulfate. This increase in soluble copper is accompanied by an increase in the relative amount of low molecular weight (7,000 to 20,000) macromolecular-bound copper and a decrease in the relative amount of high molecular weight (greater than 20,000) copper. The major low molecular weight copper protein has been isolated from copper-intoxicated mung bean plants by a combination of ammonium sulfate fractionation, gel filtration, and ion exchange chromatography. It was identified as mung bean plastocyanin on the basis of its molecular weight, optical behavior, and amino acid composition. No evidence was found for a low molecular weight copper-binding protein corresponding to mammalian thionein or chelatin.     

Increased Larval Growth and Preference for Virus-Infected Leaves by the Mexican Bean Beetle, Epilachna varivestis Mulsant, a Plant Virus Vector

Phaseolus vulgaris L. cv. 'Black Valentine' is a systemic host for the plant viruses Southern bean mosaic virus (SBMV) and bean pod mottle virus (BPMV). The Mexican bean beetle, Epilachna varivestis Mulsant, is a vector of SBMV and BPMV. Our objective was to determine if the interaction of SBMV and BPMV with 'Black Valentine' bean plants would affect beetle behavior and growth. In adult feeding preference test assays, beetles preferred and ingested more of the virus-infected bean leaf tissue than the noninfected leaf tissue. Beetle larvae that fed on SBMV- or BPMV-infected plants weighed more than those that fed on healthy plants. Our experiments suggest that there might be a mutually beneficial relationship between the beetle and the viruses that it vectors. The virus benefits from being transmitted and the beetle benefits from better larval growth when feeding on virus-infected leaf tissue. This study further demonstrates the complexity of relationships between multiple organisms.     

An Antibody to the Castor Bean Glyoxysomal Lipase (62 kD) also Binds to a 62 kD Protein in Extracts from Many Young Oilseed Plants

An antibody raised against purified glyoxysomal lipase (triacylglycerol hydrolase EC 3.1.1.3.) from castor bean (relative molecular weight of 62,000) also binds to a protein with a relative molecular weight of 62,000 in extracts of food reserve tissues from many young oilseed plants. These plants include Brassica napus L., Zea mays L., Arachis hypogaea L., Glycine max L., Gossipium hirsutum L., Cucurbita pepo L., Helianthus annuus L., Pisum sativum L., and Cicer arietinum L. The antibody caused inhibition of triacylglycerol hydrolysis by the lipases in extracts from seedlings of corn, oilseed rape, castor bean, soybean, and peanut. The pattern of antilipase binding to the 62 kilodalton protein in subcellular fractions from these other seedlings was consistent with the patterns of lipase activity reported in the literature and it is suggested that lipases from these oil seeds all have a subunit with a molecular weight of 62,000. The protein was only found in the food reserve tissues and was not present in extracts of roots and leaves of mature plants. In addition, the immunoreactive 62 kilodalton polypeptide was not detectable in lima beans and only at very low levels in kidney beans. Both these seeds are known to contain very little storage lipid and would not be expected to contain lipase. With the exception of the acid lipase of castor bean, ungerminated seeds do not generally contain active lipases. The immunoreactive 62 kilodalton protein could not be detected in the ungerminated seeds of most plants and only at very low low levels in others.     

Low molecular weight derivatives of different carrageenan types and their antiviral activity

A number of low molecular weight (LMW) fractions of carrageenans with different structural types were obtained by free radical depolymerization (H₂O₂), mild acid hydrolysis (HCl), and a specific enzyme. Three samples of carrageenans were depolymerized: kappa-carrageenan from Chondrus armatus, kappa-carrageenan from Kappaphycus alvarezii, and kappa/beta-carrageenan from Tichocarpus crinitus with initial molecular weights of 250, 390, and 400 kDa, respectively. The chemical depolymerization by two methods resulted to LMW derivatives of carrageenans with molecular weight from 1.2 to 3.5 kDa. Oligosaccharides of kappa- and kappa/beta-carrageenans with molecular weight of 2.2 and 4.3 kDa, respectively, were obtained after enzymatic depolymerization by recombinant kappa-carrageenase from Pseudoalteromonas carrageenovora. It was shown that the antiviral activity of high molecular weight carrageenans against tobacco mosaic virus was higher than that of their LWM derivatives independently on the depolymerization method. The method of depolymerization had some influence on the antiviral activity of carrageenan. LMW derivatives of kappa- and kappa/beta-carrageenans obtained by mild acid hydrolysis showed higher antiviral activity than the products of free radical depolymerization. The oligosaccharides prepared by enzymatic degradation possessed the lowest activity.     

Viral suppression of systemic silencing

RNA silencing in plants is a form of antiviral defense that was originally discovered from the anomalous effects of transgenes. The process is associated with a systemic signal, presumed to be RNA, and is suppressed by plant virus-encoded proteins. One of these proteins, the 2b protein of cucumber mosaic virus, prevents systemic spread of the signal molecule but, curiously, is located in the nucleus of infected cells. The antiviral role of silencing might also apply in animals because a suppressor of silencing encoded by an insect virus was identified recently.     

Selenium speciation profiles in selenite-enriched soybean (Glycine Max) by HPLC-ICPMS and ESI-ITMS

Soybean (Glycine Max) plants were grown in soil supplemented with sodium selenite. A comprehensive selenium profile, including total selenium concentration, distribution of high molecular weight selenium and characterization of low molecular weight selenium compounds, is reported for each plant compartment: bean, pod, leaf and root of the Se-enriched soybean plants. Two chromatographic techniques, coupled with inductively coupled plasma mass spectrometry (ICPMS) for specific selenium detection, were employed in this work to analyze extract solutions from the plant compartments. Size-exclusion chromatography revealed that the bean compartment, well-known for its strong ability to make proteins, produced high amounts (82% of total Se) of high molecular weight selenospecies, which may offer additional nutritional value and suggest high potential for studying proteins containing selenium in plants. The pod, leaf and root compartments primarily accumulate low molecular weight selenium species. For each compartment, low molecular weight selenium species (lower than 5 kDa) were characterized by ion-pairing reversed phase HPLC-ICPMS and confirmed by electrospray ionization ion trap mass spectrometry (ESI-ITMS). Selenomethionine and selenocystine are the predominant low molecular weight selenium compounds found in the bean, while inorganic selenium was the major species detected in other plant compartments.     

Modulation of plant resistance to diseases by water-soluble chitosan

Low-molecular-weight water-soluble chitosan with a molecular weight of 5 kDa obtained after enzymatic hydrolysis of native crab chitosan was shown to display an elicitor activity by inducing the local and systemic resistance of Solanumi tuberosum potato and Lycopesicon esculentum tomato to Phytophthora infestans and nematodes, respectively. Chitosan induced the accumulation of phytoalexins in tissues of host plants, decreased the total content and changed the composition of free sterols producing adverse effects on infesters, activated chitinases, beta-glucanases, and lipoxygenases, and stimulated the generation of reactive oxygen species. The activation of protective mechanisms in plant tissues inhibited the growth of taxonomically different pathogens (parasitic fungus Phytophthora infestans and root knot nematode Meloidogyne incognita).     

Isolation and Characterization of a Virus Inhibitor from Spinach (Spinacia oleracea L.)

A virus inhibiting protein (VI) was isolated from spinach (Spinacia oleracea L.). The VI inhibited infections of test plants with plus- and minus-strand RNA viruses. Inoculation of both local lesion and systemic hosts with TMV in the presence of varying amounts of the VI resulted in typical dose response curves for the number of local lesions or the amount of virus respectively. The lowest concentration of VI leading to a significant reduction in the number of local lesions was 0.06 μg/ml. The VI was found to inhibit local lesion formation only when applied within 2–3 h p.i. but still reduced the number of local lesions when applied up to 9 h prior to virus inoculation. The antiviral activity could be attributed to a protein of molecular weight 29,000 dalton with an isoelectric point of 10.3. Its activity was destroyed by heating for 30 min to 70°C. These characteristics resemble those of other virus inhibiting proteins described for members of the order Caryophyllales such as the Phytolacca inhibitor against which a serological relationship was obtained.     

Effect of sowing date and straw mulch on virus incidence and aphid infestation in organically grown faba beans (Vicia faba)

The effect of sowing date on aphid infestation and the incidence of aphid-transmitted viruses were investigated in organically managed, small-scale field experiments with two faba bean cultivars over 3 years (2002–04). As an additional factor, straw mulch was applied in 2 of the 3 years shortly before the start of vector activity in May. Virus incidence was determined using enzyme-linked immunosorbent assay and immunoelectron microscopy. Aphid flight activity was monitored using standard yellow water traps. Bean colonising aphids were assessed throughout the vegetation period by counting the number of plants infested with Acyrthosiphon pisum , Megoura viciae and Aphis fabae . Pea enation mosaic virus and bean yellow mosaic virus were the most abundant aphid-transmitted viruses, being detected in 22–54% and 9–69%, respectively, of the total number of virus-infected plants analysed per year. Further aphid-transmitted viruses found in faba bean were bean leaf roll virus, beet western yellows virus, clover yellow vein virus (in 2002) and soybean dwarf virus (in 2004). A. pisum was the predominant aphid species colonising faba bean plants. Early sowing compared with late sowing led to a significant reduction of the total virus incidence in faba bean in all 3 years. However, significantly decreased levels of A. pisum colonisation as a result of early sowing were observed only in 1 year and one cultivar. Irrespective of sowing date, straw mulching had no significant effects on virus incidence and aphid colonisation. Compared with late sowing, early sowing significantly increased bean yield in all 3 years and kernel weight in 2 years, whereas straw mulching had no effect on yield.     

Subcellular distribution and chemical form of cadmium in bean plants

The subcellular distribution and chemical form of Cd in bean plants grown in nutrient solutions containing Cd were investigated. Cd was accumulated mainly in roots and to a minor extent in leaves. Subcellular fractionation of Cd-containing tissues (pH 7.5) showed that more than 70% of the element was localized in the cytoplasmic fraction in roots as well as in leaves. Little Cd (8 to 14%) was bound either to the cell wall fraction or to the organelles. Gel filtration of the soluble fraction showed Cd to be associated mainly with 5,000 to 10,000 molecular weight components in roots, and 700 to 5,000 molecular weight components in leaves. Small amounts of Cd were found in the high molecular weight proteins (molecular weight 150,000). Only traces of Cd could be detected as a free ion. Chemical characterization of the low molecular weight components resulted in the identification of nine amino acids which were identical in roots and leaves. Cd in bean plants is assumed to be bound to peptides and/or proteins of low molecular weight.     

Tannins from Hamamelis virginiana Bark Extract: Characterization and Improvement of the Antiviral Efficacy against Influenza A Virus and Human Papillomavirus

Antiviral activity has been demonstrated for different tannin-rich plant extracts. Since tannins of different classes and molecular weights are often found together in plant extracts and may differ in their antiviral activity, we have compared the effect against influenza A virus (IAV) of Hamamelis virginiana L. bark extract, fractions enriched in tannins of different molecular weights and individual tannins of defined structures, including pseudotannins. We demonstrate antiviral activity of the bark extract against different IAV strains, including the recently emerged H7N9, and show for the first time that a tannin-rich extract inhibits human papillomavirus (HPV) type 16 infection. As the best performing antiviral candidate, we identified a highly potent fraction against both IAV and HPV, enriched in high molecular weight condensed tannins by ultrafiltration, a simple, reproducible and easily upscalable method. This ultrafiltration concentrate and the bark extract inhibited early and, to a minor extent, later steps in the IAV life cycle and tannin-dependently inhibited HPV attachment. We observed interesting mechanistic differences between tannin structures: High molecular weight tannin containing extracts and tannic acid (1702 g/mol) inhibited both IAV receptor binding and neuraminidase activity. In contrast, low molecular weight compounds (<500 g/mol) such as gallic acid, epigallocatechin gallate or hamamelitannin inhibited neuraminidase but not hemagglutination. Average molecular weight of the compounds seemed to positively correlate with receptor binding (but not neuraminidase) inhibition. In general, neuraminidase inhibition seemed to contribute little to the antiviral activity. Importantly, antiviral use of the ultrafiltration fraction enriched in high molecular weight condensed tannins and, to a lesser extent, the unfractionated bark extract was preferable over individual isolated compounds. These results are of interest for developing and improving plant-based antivirals.     

Relationships among strains of bean common mosaic virus and blackeye cowpea mosaic virus - members of the potyvirus group

In host-range studies, bean common mosaic virus strains (BCMV-NL1, -NL3 and -NY 15) usually induced distinct systemic symptoms in susceptible bean cultivars and latent infection in several Vigna genotypes (except NY15 which gave mosaic symptoms in the latter), while blackeye cowpea mosaic virus (B1CMV-W) caused distinct systemic symptoms in several Vigna genotypes and only weak systemic symptoms in a few bean genotypes only. Biologically, B1CMV-W was closest to BCMV-NY15 and less close to -NL1. When using antisera to the three BCMV strains and five strains of B1CMV (including a strain originally considered cowpea aphid-borne mosaic virus CAMV-Mor) in SDS-immunodiffusion and ELISA, BCMV-NL1 and -NY15 were found to be closely related to each other and to BICMV-Fla, -NR and -W, and less closely to BICMV-Ind and -Mor. Serological relationships of BCMV-NL1 and -NY15 to BCMV- NL3 were more distant, which is in line with the biological distinction of NL3 in causing temperature-independent necrosis in bean cultivars with the necrosis gene I. PAGE analysis of coat proteins revealed that the three strains of BCMV and B1 CMV-W have similar but non-identical molecular masses. Although molecular hybridisation may further elucidate quantitative relationships between potyvir-uses, variation within and among the potyviruses may continue to pose problems in their classification and identification.     

The effect of size and acetylation degree of chitosan derivatives on tobacco plant protection against Phytophthora parasitica nicotianae

Enzymatic degradation of chitosan polymer with Pectinex Ultra SPL was used to obtain derivatives with biological potential as protective agents against Phytophthora parasitica nicotianae (Ppn) in tobacco plants. The 24 h hydrolysate showed the highest Ppn antipathogenic activity and the chitosan native polymer the lowest. The in vitro growth inhibition of several Phytophthora parasitica strains by two chitosans of different DA was compared. While less acetylated chitosan (DA 1%) fully inhibited three P. parasitica strains at the doses 500 and 1000 mg/l the second polymer (DA 36.5%) never completely inhibited such strains. When comparing two polymers of similar molecular weight and different DA, again the highest antipathogenic activity was for the less acetylated polymer. However, degraded chitosan always showed the highest pathogen growth inhibition. Additionally, a bioassay in tobacco seedlings to test plant protection against Ppn by foliar application demonstrated that partially acetylated chitosan and its hydrolysate induced systemic resistance and higher levels of glucanase activity than less acetylated chitosan. Similarly, when treatments were applied as seeds coating before planting, about 46% of plant protection was obtained using chitosan hydrolysate. It was concluded that, while less acetylated and degraded chitosan are better for direct inhibition of pathogen growth, partially acetylated and degraded chitosan are suitable to protect tobacco against P. parasitica by systemic induction of plant resistance.     

Carbohydrate-functionalized chitosan fiber for influenza virus capture

The high transmissibility and genetic variability of the influenza virus have made the design of effective approaches to control the infection particularly challenging. The virus surface hemagglutinin (HA) protein is responsible for the viral attachment to the host cell surface via the binding with its glycoligands, such as sialyllactose (SL), and thereby is an attractive target for antiviral designs. Herein we present the facile construction and development of two SL-incorporated chitosan-based materials, either as a water-soluble polymer or as a functional fiber, to demonstrate their abilities for viral adhesion inhibition and decontamination. The syntheses were accomplished by grafting a lactoside bearing an aldehyde-functionalized aglycone to the amino groups of chitosan or chitosan fiber followed by the enzymatic sialylation with sialyltransferase. The obtained water-soluble SL-chitosan conjugate bound HA with high affinity and inhibited effectively the viral attachment to host erythrocytes. Moreover, the SL-functionalized chitosan fiber efficiently removed the virus from an aqueous medium. The results collectively demonstrate that these potential new materials may function as the virus adsorbents for prevention and control of influenza. Importantly, these materials represent an appealing approach for presenting a protein ligand on a chitosan backbone, which is a versatile molecular platform for biofunctionalization and, thereby, can be used for not only antiviral designs, but also extensive medical development such as diagnosis and drug delivery.     

A systemic resistance inducing antiviral protein with N-glycosidase activity from Bougainvillea xbuttiana leaves

An antiviral protein from Bougainvillea xbuttiana leaves induced systemic resistance in host plants N. glutinosa and Cyamopsis tetragonoloba against TMV and SRV, respectively which was reversed by actinomycin D, when applied immediately or shortly after antiviral protein treatment. When the inhibitor was applied to the host plant leaves post inoculation, it was effective if applied upto 4 h after virus infection. It also delayed the expression of symptoms in systemic hosts of TMV. The inhibitor showed characteristic N-glycosidase activity on 25S rRNA of tobacco ribosomes, suggesting that it could also be interfering with virus multiplication through ribosome-inactivation process.     

Biospecific fractionation of chitosan

We have previously reported that, although a fully de-N-acetylated chitosan does not bind to hen egg white lysozyme, chitosans with a low fraction of N-acetylated units (FA) bind biospecifically to lysozyme with an affinity strongly dependent upon pH and ionic strength and without concomitant cleavage of glycosidic linkages. In this study, we report on the fractionation of a low FA chitosan with low molecular weight by biospecific adsorption of the chitosan molecules containing N-acetyl groups to immobilized lysozyme. Hen egg white lysozyme was immobilized to CNBr-activated Sepharose 4B, and a chitosan with a fraction of N-acetylated units of 0.045 and a weight average degree of polymerization (DPw) of 22 was applied to the column at suitable conditions for biospecific binding (pH 5.7, 0.15 M NaCl). The chitosan could be separated into two fractions, one that was not adsorbed to the lysozyme-column and one that was adsorbed and could be eluted by decreasing the pH and the ionic strength (0.08 M acetic acid of pH 3.0). The fractions were analyzed and the fraction that was not adsorbed was found to be fully de-N-acetylated chitosan with a DPw of 18, whereas the fraction that was adsorbed was a chitosan with FA of 0.080 and DPw of 24. Experimental data were compared with data from theoretical calculations, which was used to calculate the fraction of chitosan molecules with and without acetyl groups, showing good correlation between experimental and theoretical results.     

VIRUSES OF COWPEA, VIGNA UNGUICULATA L. (WALP.), IN NIGERIA

The cowpea strain of tobacco mosaic virus was isolated from a range of leguminous hosts at Ibadan, but was rare in cultivated crops. Systemic symptoms in species infected experimentally are described.
A new virus of cowpea was also found in Nigeria. The physical properties (thermal inactivation point 56° C., dilution end-point 1/50,000 and longevity in vitro 4 days at 25° C.) differ from those for cowpea viruses reported elsewhere and the name cowpea yellow mosaic virus is proposed. This virus produces local lesions in French bean ( Phaseolus vulgaris L.) and local and systemic lesions in Bengal bean ( Mucuna aterrima Holland), but does not infect other leguminous hosts. The virus was purified and an antiserum prepared against it.
Both viruses are transmitted by a beetle ( Ootheca mutabilis Sahlb.) which loses infectivity within 48 hr. of leaving plants infected with either or both viruses.     

Different Dicer-like protein components required for intracellular and systemic antiviral silencing in Arabidopsis thaliana

Eukaryotes employ RNA silencing as an innate defense system against invading viruses. Dicer proteins play the most crucial role in initiating this antiviral pathway as they recognize and process incoming viral nucleic acids into small interfering RNAs. Generally, 2 successive infection stages constitute viral infection in plants. First, the virus multiplies in initially infected cells or organs after viral transmission and then the virus subsequently spreads systemically through the vasculature to distal plant tissues or organs. Thus, antiviral silencing in plants must cope with both local and systemic invasion of viruses. In a recent study using 2 sets of different experiments, we clearly demonstrated the differential requirement for Dicer-like 4 (DCL4) and DCL2 proteins in the inhibition of intracellular and systemic infection by potato virus X in Arabidopsis thaliana. Taken together with the results of other studies, here we further discuss the functional specificity of DCL proteins in the antiviral silencing pathway.     

Serological and molecular characterisations of the Egyptian isolate of Bean common mosaic virus

Bean common mosaic virus (BCMV) was isolated from the naturally infected bean plants collected from the Kafr El-Sheikh and El-Gharbia Governorates. BCMV induced sever mosaic, vein banding, malformation, leaf curling and stunting on bean plants cv. Giza 6. The isolated virus was propagated in bean plants cv. Giza 6. The identification of BCMV was carried out serologically by an indirect enzyme-linked immunosorbent assay using BCMV antiserum. Positive reaction indicated that the virus under study was related serologically to Potyvirus. The molecular biology techniques were used to identify and characterise the coat protein gene of BCMV. Oligonucleotide primers were designed for BCMV according to the published nucleotide sequences of BCMV and were successfully amplified with a DNA fragment (300 bp) from BCMV CP gene by RT-PCR. The total RNA was extracted from bean leaves and was reverse-transcribed and amplified using the oligonucleotide primer. The amplified product was analysed by gel electrophoresis. Also, Southern and dot blot hybridisations were used to establish the authenticity and specificity to the RT-PCR-amplified products of BCMV. The nucleotide sequences of the Egyptian isolate of BCMV/CP showed similarity with an isolate (BCMV-NY 15) which belongs to Puerto Rico.