Chemical modification of silk sericin in lithium chloride/dimethyl sulfoxide solvent with 4-cyanophenyl isocyanate

This paper reports chemical modification of silk sericin in LiCl/dimethyl sulfoxide (DMSO) solvent with 4-cyanophenyl isocyanate. Sericin is a highly hydrophilic protein secreted by Bombyx mori, serving as a protein glue in a cocoon. LiCl/DMSO was found to be a good solvent of sericin and useful for homogeneous modification of its abundant hydroxyl groups under nonaqueous condition. Fourier transform infrared (FTIR) analysis of the modified sericins revealed that 4-cyanophenyl groups were incorporated into sericin molecules mainly through urethane linkages. Several characteristics of the modified sericins such as solubility characteristic, hygroscopic property, and thermal stability were investigated. Secondary structure analysis using FTIR spectra suggested that formation of strong intermolecular hydrogen bonds was inhibited by the modification that is probably attributable to the incorporation of bulky 4-cyanophenyl groups. These results demonstrate that chemical modification of sericin using LiCl/DMSO solvent markedly alters its characteristics.     

Construction of a 'turn-on' fluorescent probe system for His-tagged proteins

Hexahistidine ((His)(6)) tags are used to purify genetically engineered proteins. Herein, we describe the construction of a 'turn-on' fluorescent probe system that consists of the fluorescence quencher, Dabcyl, conjugated to (His)(6), and fluorescent tetramethylrhodamine conjugated to nitrilotriacetic acid, which, in the presence of Ni(2+), can bind (His)(6). The system is turned off when Dabcyl-(His)(6) is bound to the fluorescent nitrilotriacetic acid derivative. The binding strength of this system was assessed using electrospray ionization mass spectrometry, fluorescence correlation spectroscopy, and fluorescence intensity distribution analysis-polarization. Although there was no significant enhancement in fluorescence after addition of an equimolar amount of ubiquitin, the fluorescence increased from 14% to 40% of its initial intensity when an equimolar amount of (His)(6)-ubiquitin was added. Therefore, this system should be able to specifically recognize (His)(6)-proteins with good resolution and has the additional advantage that a washing step is not required to remove fluorescent probe, that is, not bound to the (His)(6)-protein.     

Polyamines and jasmonic acid induce plasma membrane potential variations in lima bean

Exogenous polyamines [cadaverine (Cad), putrescine (Put), spermidine (Spd) and spermine (Spm)] elicit the production of volatiles in Lima bean (Phaseolus lunatus). Among the tested PAs, Spm induces the production of some volatile terpenoids that are known to be induced by the spider mite Tetranychus urticae. Spm treatment elicits the biosynthesis of Jasmonic acid (JA), a phytohormone known to regulate the production of the volatile terpenoids. The treatment with JA together with Spm resulted in the increased volatile emission, and predatory mites Phytoseiulus persimilis preferred JA and Spm-treated leaves over those treated with JA alone.⁵ JA and Spm treatment has no effects on polyamine oxidase (PAO) and Cu-amine oxidase (CuAO) but has a significant induction of calcium influx, ROS production, enzyme activities for NADPH-oxidase complex, superoxide dismutase, catalase, ascorbate peroxidase, glutathione reductase and glutathione peroxidase, and gene expressions except for NADPH-oxidase complex.⁵ Here, we report that a plasma membrane potential (V_m) depolarization was observed after polyamine perfusion with an increasing trend: Spm, Cad, Put and Spd. JA perfusion did not alter V_m but the perfusion of JA and the polyamines significantly increased Cad and Put V_m depolarization. When JA was perfused with polyamines, a negative correlation was found between V_m depolarization and the number of amino group of the polyamines tested.Key words: polyamines, lima bean, herbivore-induced volatile organic compounds, calcium and ROS signalling, jasmonic acid, quantitative gene expression, transmembrane potentialPolyamines are involved in plants’ stress responses and growth. By activating biosynthesis of nucleic acids, polyamines concern the plant growth and differentiation.^1–3 Furthermore, it has been reported that polyamines are involved in the response against environmental stress and plant disease.^1–4 We recently reported that exogenously applied polyamines ∼diamines [cadaverine (Cad), putrescine (Put)], triamine [spermidine (Spd)] and tetraamine ]spermine (Spm)]∽ induce volatile emission in Lima bean leaves.⁵ Membrane potentials (V_m) and intracellular calcium variations were also studied in Lima bean leaves after perfusion with the polyamines and with these addition of JA and here we report on these additional results.The primary candidate for intercellular signaling in higher plants is the stimulus-induced change in V_m.⁶ The plasma membrane potential (V_m), which lies in the range of −50 to −200 mV in Lima bean leaves,⁷ may be shifted either to more negative (hyperpolarization) or to more positive values (depolarization) in response to various biotic or abiotic stresses.Measurement of V_m were performed and data statistically treated as previously described (ANOVA and Tukey-Kramer’s HSD test).⁷ Perfusion with the polyamines (Fig. 1 single arrow) shows a specific response of the leaf tissues with a different V_m depolarization, depending on the polyamine. In general, a V_m depolarization was observed after polyamine perfusion with an increasing trend: Spm, Cad, Put and Spd (Fig. 1). Spm and Spd V_m depolarization values were significantly different (p < 0.05) from all other polyamines, whereas no significant difference was found between Put and Cad V_m depolarization (p = 0.435). In all cases, V_m depolarization was reversed by washing polyamine-treated leaves with a fresh buffer solution (Fig. 1 double arrow); however, a full recovery of the V_m was observed only for Put (Fig. 1). The linearization of the data from Figure 1 allowed to calculate the rate of V_m depolarization after perfusion of the polyamines which was higher for Spd (6.0 mV min⁻¹; R = 0.96), equal for Put and Cad (4.8 mV min⁻¹; Put R = 0.95; Cad R = 0.97) and lower for Spm (3.0 mV min⁻¹; R = 0.96).Open in a separate windowFigure 1Effect of 1 mM polyamines (arrow) on the V_m of Lima bean palisade cells. Spermine (Spm) caused the lowest V_m depolarization, whereas spermidine (Spd) showed the highest values of V_m depolarization. intermediate values were found when putrescine (Put) and cadaverine (cad) were perfused. after washing the tissues with fresh buffer (double arrow) V_m was always hyperpolarized, however the initial potential was recovered only for Put, while for all other polyamines the V_m never reached the initial values. Metric bars indicate standard deviation.Perfusion with JA caused a slight and not significant (p = 0.332) V_m depolarization (Fig. 2) with respect to control. The addition of JA caused a significant increase (p < 0.01) in V_m depolarization when perfused with Cad, with respect to the sole perfusion with Cad (Fig. 1). The same was observed when JA was perfused with Put, whereas not significant differences were observed when Spm (p = 0.513) and Spd (p = 0.107) were perfused with JA (Fig. 2), with respect to the sole perfusion with Spm and Spd (Fig. 1). The linearization of the data from Figure 2 allowed to calculate the rate of V_m depolarization after perfusion of the polyamines + JA, which was higher for Cad (24.40 mV min⁻¹; R = 0.99), almost equal for Put and Spd (Put: 14.21 mV min⁻¹, R = 0.99; Spd: 13.49 mV min⁻¹, R = 0.99) and lower for Spm (1.34 mV min⁻¹; R = 0.93). For JA the rate of V_m depolarization was 0.19 mV min⁻¹ (R = 0.96). With the addition of JA, a negative correlation was found between V_m depolarization and the number of amino group of the polyamines tested.Open in a separate windowFigure 2Effect of 1 mM polyamines + 0.1 mMJA (arrow) on the V_m of Lima bean palisade cells. the perfusion with Ja did not cause any variation in the V_m. addition of JA to Spm and Spd caused the same V_m depolarization observed in the absence of JA, whereas when JA was added to Put and Cad a stronger and significantly different V_m depolarization was observed. even in this case washing the tissues with fresh buffer (double arrow) caused a V_m hyperpolarized, however in this case Spd reached V_m values significantly more negative that the initial V_m. Metric bars indicate standard deviation. For abbreviations see Figure 1.Since ion fluxes through channels directly influence V_m, it seems reasonable to assume that molecules able to act on channel activity might be considered as important factors inducing electrical signals. Among the various channels, calcium and potassium channels are predominantly involved in cell signaling.⁸ In the present study, rapid and reversible V_m depolarization observed upon perfusion of Lima bean mesophyll cells with polyamines was found to be significantly increased when JA was added to Cad and Put. The reversibility of the V_m may be linked to the overall physico-chemical amphiphilic properties of polyamines, probably depending on non covalent interaction with plasma membrane molecules, as polyamines occur in plants in free form, bound electrostatically to negatively charged molecules, and conjugated to small molecules and proteins.⁹ Liu et al.¹⁰ showed that Spm, Spd, Cad and Put strongly inhibited opening and closing of stomata in Vicia faba, suggesting that polyamines target inward potassium channels in guard cells and modulate stomatal movements, so providing a link between abiotic stress, polyamine levels and stomatal regulation. Moreover, the transport of polyamines across the plasma membrane of plant cells is energy-dependent and calcium is involved in the uptake mechanism.^1,11 Both mechanisms can be correlated to the observed V_m depolarization, and the positive correlation between intracellular Ca²⁺ concentration⁵ and V_m depolarizing activity of polyamines confirms the involvement of Ca²⁺ during polyamine uptake.¹¹     

Histopathology of growth anomaly affecting the coral, Montipora capitata: implications on biological functions and population viability

Growth anomalies (GAs) affect the coral, Montipora capitata, at Wai'ōpae, southeast Hawai'i Island. Our histopathological analysis of this disease revealed that the GA tissue undergoes changes which compromise anatomical machinery for biological functions such as defense, feeding, digestion, and reproduction. GA tissue exhibited significant reductions in density of ova (66.1-93.7%), symbiotic dinoflagellates (38.8-67.5%), mesenterial filaments (11.2-29.0%), and nematocytes (28.8-46.0%). Hyperplasia of the basal body wall but no abnormal levels of necrosis and algal or fungal invasion was found in GA tissue. Skeletal density along the basal body wall was significantly reduced in GAs compared to healthy or unaffected sections. The reductions in density of the above histological features in GA tissue were collated with disease severity data to quantify the impact of this disease at the colony and population level. Resulting calculations showed this disease reduces the fecundity of M. capitata colonies at Wai'ōpae by 0.7-49.6%, depending on GA severity, and the overall population fecundity by 2.41±0.29%. In sum, GA in this M. capitata population reduces the coral's critical biological functions and increases susceptibility to erosion, clearly defining itself as a disease and an ecological threat.     

Volatile C6-aldehydes and Allo-ocimene activate defense genes and induce resistance against Botrytis cinerea in Arabidopsis thaliana

Green leafy volatiles or isoprenoids are produced after mechanical wounding or pathogen/herbivore attacks in higher plants. We monitored expression profiles of the genes involved in defense responses upon exposing Arabidopsis thaliana to the volatiles. Among the genes investigated, those known to be induced by mechanical wounding and/or jasmonate application, such as chalcone synthase (CHS), caffeic acid-O-methyltransferase (COMT), diacylglycerol kinase1 (DGK1), glutathione-S-transferase1 (GST1) and lipoxygenase2 (LOX2), were shown to be induced with (E)-2-hexenal, (Z)-3-hexenal, (Z)-3-hexenol or allo-ocimene (2,6-dimethyl-2,4,6-octatriene). A salicylic acid-responsive gene, pathogenesis-related protein2 (PR2), was not induced by the volatiles. Detailed analyses of the expression profiles showed that the manner of induction varied depending on either the gene monitored or the volatile used. A chemically inert compound, (Z)-3-hexenol, was also potent, which suggested that chemical reactivity was not the sole requisite for the inducing activity. With a jasmonate-insensitive mutant (jar1), the induction by the volatiles was mostly suppressed, however, that of LOX2 was unaltered. An ethylene-insensitive mutant (etr1) showed responses almost identical to the wild type, with minor exceptions. From these observations, it was suggested that both the jasmonate-dependent and -independent pathways were operative upon perception of the volatiles, while the ETR1-dependent pathway was not directly involved. When Botrytis cinerea was inoculated after the volatile treatment, retardation of disease development could be seen. It appears that volatile treatment could make the plants more resistant against the fungal disease.     

Differential metabolisms of green leaf volatiles in injured and intact parts of a wounded leaf meet distinct ecophysiological requirements

Almost all terrestrial plants produce green leaf volatiles (GLVs), consisting of six-carbon (C6) aldehydes, alcohols and their esters, after mechanical wounding. C6 aldehydes deter enemies, but C6 alcohols and esters are rather inert. In this study, we address why the ability to produce various GLVs in wounded plant tissues has been conserved in the plant kingdom. The major product in completely disrupted Arabidopsis leaf tissues was (Z)-3-hexenal, while (Z)-3-hexenol and (Z)-3-hexenyl acetate were the main products formed in the intact parts of partially wounded leaves. (13)C-labeled C6 aldehydes placed on the disrupted part of a wounded leaf diffused into neighboring intact tissues and were reduced to C6 alcohols. The reduction of the aldehydes to alcohols was catalyzed by an NADPH-dependent reductase. When NADPH was supplemented to disrupted tissues, C6 aldehydes were reduced to C6 alcohols, indicating that C6 aldehydes accumulated because of insufficient NADPH. When the leaves were exposed to higher doses of C6 aldehydes, however, a substantial fraction of C6 aldehydes persisted in the leaves and damaged them, indicating potential toxicity of C6 aldehydes to the leaf cells. Thus, the production of C6 aldehydes and their differential metabolisms in wounded leaves has dual benefits. In disrupted tissues, C6 aldehydes and their α,β-unsaturated aldehyde derivatives accumulate to deter invaders. In intact cells, the aldehydes are reduced to minimize self-toxicity and allow healthy cells to survive. The metabolism of GLVs is thus efficiently designed to meet ecophysiological requirements of the microenvironments within a wounded leaf.     

Learning of host-infested plant volatiles in the larval parasitoid Cotesia kariyai

The ability to learn plant volatiles in Cotesia kariyai females was examined by wind tunnel bioassays. Searching experience on a host-infested corn plant increased subsequent flight responses of females to the infested plant. Females experiencing host by-products together with the volatiles extracted from infested leaves one time showed an increased response. However, such behavioral changes were not observed in females which experienced only the host by-products or the volatiles. Thus, the increased response is considered to be preference learning. Multiple experiences of C. kariyai with host by-products together with the volatiles did not increase their flight response to the volatiles. Furthermore, this learned response gradually decreased within 2 days. These behavioral modifications based on experience would be advantageous for C. kariyai to locate their polyphagous hosts efficiently.