Antifungal and physical characteristics of modified denture base acrylic incorporated with silver nanoparticles

doi: 10.1111/j.1741‐2358.2011.00489.x Antifungal and physical characteristics of modified denture base acrylic incorporated with silver nanoparticles Objective: This study evaluated the antifungal and physical characteristics of denture base acrylic combined with silver nanoparticles. Materials and methods: Polymerized denture acrylic disc specimens containing 0 (control), 1.0, 5.0, 10.0, 20.0 and 30.0 wt% of silver nanoparticles were placed on separate culture plate dish and 100 ìL samples of yeast suspension of Candida albicans strain were inoculated on each specimens and incubated at 37°C, for 24 h. The antifungal effects were evaluated as a number of viable cells in retrieved fungal suspension. To characterize physical aspects, specimens were tested for elution of silver cation (Ag⁺) at 24 h and 30th day, thermal analysis (TG/DTA), scanning electron microscope and energy dispersed X‐ray analysis (SEM/EDX) and color stability. Results: Significant reduced CFU was exhibited at 20.0 and 30.0 wt% of silver nanoparticles incorporated (p < 0.01) and Ag⁺ elution from specimens (maximum 0.356 ± 0.11 mg/L) contributed little to the antifungal activity considering MIC of Ag⁺ in this study (3.0 mg/L). The successful synthesis of modified denture acrylic containing silver nanoparticles was accessed by TG/DTA and EDX analysis. Conclusion: The modified denture base acrylic combined with silver nanoparticles displayed antifungal properties and acted like latent antifungal material itself with low‐releasing Ag⁺, however, the improvement of poor color stability was still required.     

Bioaccumulation of silver by a multispecies community of bacteria

A stable community of bacteria that had unusually high tolerance of soluble silver was isolated from soil by chemostat enrichment. The community consisted of three bacteria: Pseudomonas maltophilia, Staphylococcus aureus and a coryneform organism. The pseudomonas was primarly responsible for the silver resistance. The tolerance of high silver concentrations, up to 100 mM Ag⁺, was greatly reduced when the community was grown in the absence of silver. Pseudomonas maltophilia comprised approximately 50% by numbers of the community when grown in chemostats in the presence or absence of Ag⁺ but large fluctuations occurred in population sizes of the other two bacteria; the S. aureus population was small (less than 1%) in the presence of Ag⁺ but comparised a third of the total numbers when Ag⁺ was omitted from the medium. Silver-resistant respiration of the silveradapted community was significant even when it was confronted with high concentrations of Ag⁺. In contrast the respiration of the coryneform organism and particularly S. aureus was highly sensitive to silver. The inhibition constants for silver-sensitive respiration were 0.78 mM and 0.04 mM for silver acclimatized and nonacclimatized communities respectively.The community had great capacity for silver bioaccumulation. Maximum concentrations of over 300 mg silver per g dry weight of biomass were recorded at an accumulation rate of 21 mg Ag⁺ h^-1 (g biomass)^-1. The extent of silver removal from solution was a function of initial concentration of silver; at low external concentrations (ca. 1 mM) all the silver was rapidly removed from solution, at high concentrations (ca. 12 mM) 84% removal occurred in 15 h.     

Silver tolerance and accumulation in yeasts

Summary Debaryomyces hansenii (NCYC 459 and strain 75-21),Candida albicans (3153A),Saccharomyces cerevisiae (X2180-1B),Rhodotorula rubra (NCYC 797) andAureobasidium pullulans (IMI 45533 and ATCC 42371) were grown on solid medium supplemented with varying concentrations of AgNO₃. Although Ag⁺ is highly toxic towards yeasts, growth on solid media was still possible at Ag concentrations of 1–2 mM. Further subculture on higher Ag concentrations (up to 5 mM) resulted in elevated tolerance. The extent of Ag tolerance depended on whether Ag-containing plates were exposed to light prior to inoculation since light-mediated reduction of Ag⁺ to Ag⁰ resulted in the production of a less toxic silver species. Experimental organisms exhibited blackening of colonies and the surrounding agar during growth on AgNO₃-containing medium especially at the highest Ag concentrations tested. All organisms accumulated Ag from the medium; electron microscopy revealed that silver was deposited as electron-dense granules in and around cell walls and in the external medium. X-ray microprobe analysis indicated that these granules were metallic Ag⁰ although AgCl was also present in some organisms. Volatile and non-volatile reducing compounds were produced by several test organisms which presumably effected Ag⁺ reduction to Ag⁰.     

A method to increase silver biosorption by an industrial strain of Saccharomyces cerevisiae

 Ag⁺ biosorption by an industrial strain of Saccharomyces cerevisiae was investigated. Older (96 h old) biomass had half the biosorption capacity of younger (24 h old) biomass (0.187 and 0.387 mmol Ag⁺/g dry mass respectively). Comparisons of cell walls isolated from biomass of either age indicated that chemical composition and Ag⁺ biosorption capacity varied little over the time span examined and that cell walls from either age of culture had small Ag⁺ biosorption capacities compared to whole cells of a similar age. Silver-containing precipitates were observed both on the cell wall and within the cell, indicating that intracellular components sorbed Ag⁺. The concentration of these precipitates within the cell appeared visually to decrease with age in Ag⁺-exposed cells. Incorporation of L-cysteine into the growth medium resulted in biomass with increased silver biosorption capacities, protein and sulphydryl group content. Increasing the concentration of L-cysteine in the growth medium from 0 to 5.0 mM increased silver biosorption from 0.389 to 0.556 mmol Ag⁺/g dry mass Isolated cell walls of biomass grown in supplemented media also showed a possible link between silver biosorption capacities, protein and sulphydryl group content. No precipitates were observed in silver-exposed biomass that had been grown in the presence of 5.0 mM L-cysteine. Received: 12 April 1995 / Received revision: 7 August 1995 / Accepted: 22 August 1995     

Experimental evolution of Pseudomonas putida under silver ion versus nanoparticle stress

Whether the antibacterial properties of silver nanoparticles (AgNPs) are simply due to the release of silver ions (Ag⁺) or, additionally, nanoparticle-specific effects, is not clear. We used experimental evolution of the model environmental bacterium Pseudomonas putida to ask whether bacteria respond differently to Ag⁺ or AgNP treatment. We pre-evolved five cultures of strain KT2440 for 70 days without Ag to reduce confounding adaptations before dividing the fittest pre-evolved culture into five cultures each, evolving in the presence of low concentrations of Ag⁺, well-defined AgNPs or Ag-free controls for a further 75 days. The mutations in the Ag⁺ or AgNP evolved populations displayed different patterns that were statistically significant. The non-synonymous mutations in AgNP-treated populations were mostly associated with cell surface proteins, including cytoskeletal membrane protein (FtsZ), membrane sensor and regulator (EnvZ and GacS) and periplasmic protein (PP_2758). In contrast, Ag⁺ treatment was selected for mutations linked to cytoplasmic proteins, including metal ion transporter (TauB) and those with metal-binding domains (ThiL and PP_2397). These results suggest the existence of AgNP-specific effects, either caused by sustained delivery of Ag⁺ from AgNP dissolution, more proximate delivery from cell-surface bound AgNPs, or by direct AgNP action on the cell's outer membrane.     

Biosorption of silver ions by processed Aspergillus niger biomass

Summary An alkali treated A. niger biomass was found to efficiently sequester silver ions from dilute as well as concentrated solutions (2.5–1000 ppm Ag⁺), with an ability to bind it to a level of upto 10% of dry weight. Biosorption of silver ions was not influenced by pH between 5–7. The bound Ag⁺ could be fully desorbed by dilute HNO₃ and the biosorbent regenerated by washing with Ca²⁺/Mg²⁺ solution. This biosorbent is unique in that the mechanism of metal ion sorption has been found to be exclusively by stoichiometric exchange with Ca²⁺ and Mg²⁺ of the biosorbent.     

The effect of silver and other metal ions on the in vitro growth of root-rotting Phytophthora and other fungal species

A range of metal ions and the oxoanion WO₄^2-were toxic to zoospores of Phytophthora nicotianae parasitica in the order: Ag⁺ > Cu⁺⁺ > WO₄^2-> Ni⁺ > Co⁺⁺ > Zn⁺. The LD₅₀ for Ag⁺, 0.11 μM (11.4 ppb), compared with 1.84 μm (117 ppb) for Cu⁺⁺. Silver was similarly toxic to a range of pathogens including Pythium aphanidermatum, Thielaviopsis basicola and Fusarium oxy-sporum f.spp. Most zoospores of Phytophthora spp. were killed by Ag⁺ in the range 46–460 nM (5–50 ppb), bursting at the higher concentrations. A small sub-population of most propagules exhibited greater tolerance to silver than the whole. In 0.93 μM (100 ppb) Ag⁺ 1.4% of P. nicotianae parasitica zoospores survived but were all killed at 500 ppb. A population of P. cryptogea (1.9%) surviving 0.47 μm (50 ppb) were killed at 0.93 μM (100 ppb). Zoospore cysts and germlings showed the same sensitivity to silver. Oospores were mostly killed over the range 0.23–0.93 μm (25–100 ppb) Ag⁺, some surviving up to the lethal concentration of 9.26 μM (1000 ppb). Mycelium of P. cryptogea was generally less sensitive, with some growth occurring at 9.26 μm (100 ppb). Zoosporangiogenesis was unaffected over the range 0.47–4.65 μm (50–500 ppb). Toxicity increased with increased pH over the range 5.0–6.5. Ionic silver was lost from solution during a microscope slide bioassay by binding to the glass surface. In the presence of chloride ions, colloidal AgCl formed which was equally toxic to P. cryptogea. Silver and AgCl were further lost from solution by colloidal agglomeration - Ostwald ripening - and by AgCl adsorption to glass. Silver, < 90 nM (10 ppb) Ag⁺ as AgNO₃ and particles of silver chloride were both strongly attractive to zoospores of P. cryptogea. Spores burst or failed to germinate on entering lethal concentrations. The results are discussed in the context of the use of silver salts to control Phytophthora root-rot pathogens and the importance of ion availability in in vitro toxicity assays.     

Thiosulfate stimulates growth and alleviates silver and copper toxicity in tomato root cultures

The influence of supplemented thiosulfate (S₂O₃ ²⁻) as well as a complex of either Ag⁺ or Cu²⁺ with S₂O₃ ²⁻ in the culture medium on proliferating root cultures of tomato (Solanum lycopersicum) was investigated. The presence of 10–300 μM sodium thiosulfate (Na₂S₂O₃) in half-strength Murashige and Skoog (MS) basal salt medium promoted root elongation and proliferation of lateral roots. Growth was enhanced by 1–2 μM AgNO₃, but was completely arrested at 5 μM AgNO₃; moreover, growth inhibition was elicited by dissolved silver (Ag⁺) and by silver in silver precipitate particles. Root elongation was also inhibited by 50 μM CuSO₄ supplemented to the basal medium. Roots subjected to either AgNO₃ or CuSO₄ growth inhibiting treatments were unable to recover following transfer to medium lacking either Ag⁺ or Cu²⁺. When the basal medium was supplemented with either silver or copper in the form of silver thiosulfate complex or copper thiosulfate complex, root cultures continued to elongate and proliferate, thus either completely alleviating or diminishing the inhibitory effects of Ag⁺ and Cu²⁺, respectively. It was concluded that tomato roots sensed and responded to S₂O₃ ²⁻, hence root proliferation could be promoted by adding Na₂S₂O₃ to the medium. Moreover, a complex of Ag⁺ with S₂O₃ ²⁻ detoxified dissolved Ag⁺ and prevented the generation of toxic silver particle precipitates. Consequently, silver thiosulfate was superior to AgNO₃ in enhancing root culture. Finally, a complex of Cu²⁺ with S₂O₃ ²⁻ ligand reduced toxicity of Cu²⁺ to root cultures of tomato.     

Accumulation of silver by growing and non-growing populations of Citrobacter intermedius B6

Summary Accumulation of silver is reported for growing and non-growing populations of Citrobacter intermedius B6. In non-growing cultures a maximum uptake of 4.35% (w/w) was observed at an initial silver concentration of 2111.2 mol Ag⁺ l^-1. In contrast the maximum uptake of silver by growing bacteria was 2.81% (w/w) at an effective concentration of silver of 217.8 mol·l^-1. Silver accumulation rates in both resting (460 mol Ag⁺ g^-1 per hour) and continuously grown (41 mol Ag⁺ g^-1 per hour) bacteria are higher than previously reported. Cell fractionation and electron microscopy of continuously grown bacteria indicated that accumulation of silver was associated with the cell envelope, in the form of dense deposits of macromolecular proportions. This observation discounts simple surface adsorption as the process of accumulation in growing cultures.     

Protection of catheter surfaces from adhesion of Pseudomonas aeruginosa by a combination of silver ions and lectins

A catheter surface was modified by coating a cellulose acetate polymer. Adhesion of Pseudomonas aeruginosa ATCC 27853 to the surface was investigated by exposing bacterial cultures to three treatments: polymer impregnated with silver ions (Ag⁺), polymer surfaces coated with lectins and a combination of Ag⁺ and a lectin coating. The effective concentration of Ag⁺ providing protection against bacterial biofilm development was 100g/ml and higher. Lectins alone at 10% also showed inhibition of bacterial attachment. However, the best result was achieved against bacterial adhesion and growth on surfaces using a combination of 100 g Ag⁺/ml and a lectin coating as a surface treatment. This surface treatment was also effective against both fresh culture and a two-week-old culture containing P. aeruginosa producing exopolymers. Our results suggest that Ag⁺impregnation combined with a lectin coating warrants further investigation as a potential means of protecting catheters.     

Comparisons of Characteristics of Mercury-Tolerant Bacterium Pseudomonas oleovorans G-1 and Its Mercury-Sensitive Mutant Strain

An Hg²⁺-sensitive mutant strain was isolated from an Hg²⁺-tolerant bacterium Pseudomonas oleovorans G-1 strain by mutagenesis with N-methyl-N′-nitro-N-nitrosoguanidine. The Hg²⁺-sensitive mutant strain was about 10-times as sensitive to Hg²⁺ as the parent strain. Moreover, the mutant strain was considerably more sensitive to Cr⁶⁺ than the parent strain, but it did not show an appreciable change in sensitivity to Cd²⁺ and Cu²⁺. The mutant strain was considerably more sensitive to antibiotics achromycin, chloramphenicol and streptomycin than the parent strain. A more rigid structure was observed in the cell envelope of the mutant strain than the parent strain under transmission electron microscope. Higher amounts of DNA but less protein and RNA were found in the mutant strain compared to the parent strain. Disc electrophoretic patterns showed some differences in protein bands between the parent and mutant strain.     

Mobilization ofEscherichia coli R1 silver-resistance plasmid pJT1 by Tn5-Mob intoEscherichia coli C600

Summary Escherichia coli Rl is an Ag⁺-resistant strain that, as we have shown recently, harbours at least two large plasmids, pJT1 (83 kb) and pJT2 (77 kb). Tn5-Mob was introduced into theE. coli Rl host replicon via conjugation on membrane filters. The transfer functions of plasmid RP4-4 were provided in this process and Tn5-Mob clones mated withE. coli C600 yielded Ag⁺-resistant transconjugants. This mobilization procedure allowed transfer and expression of pJT1 Ag⁺ resistance inE. coli C600. Prior to use of Tn5-Mob mobilization, it was not possible to transfer Ag⁺-resistant determinant(s) intoE. coli by conjugation or transformation including high-voltage electroporation.E. coli C600 containing PJTI and PJT2 displayed decreased accumulation of Ag⁺ similar toE. coli R1.E. coli C600 could not tolerate 0.1 and 0.5 mM Ag⁺, rapidly accumulated Ag⁺ and became non-viable. Tn5-Mob mobilization may be useful in the study of metal resistance in bacteria, especially in strains not studied for resistance mechanisms.     

Complexes of DNA bases and Watson–Crick base pairs interaction with neutral silver Agn (n = 8, 10, 12) clusters: a DFT and TDDFT study

We study the binding of the neutral Ag_n (n = 8, 10, 12) to the DNA base-adenine (A), guanine (G) and Watson–Crick –adenine-thymine, guanine-cytosine pairs. Geometries of complexes were optimized at the DFT level using the hybrid B3LYP functional. LANL2DZ effective core potential was used for silver and 6–31 + G^** was used for all other atoms. NBO charges were analyzed using the Natural population analysis. The absorption properties of Ag_n–A,G/WC complexes were also studied using time-dependent density functional theory. The absorption spectra for these complexes show wavelength in the visible region. It was revealed that silver clusters interact more strongly with WC pairs than with isolated DNA complexes. Furthermore, it was found that the electronic charge transferred from silver to isolated DNA clusters are less than the electronic charge transferred from silver to the Ag_n–WC complexes. The vertical ionization potential, vertical electron affinity, hardness, and electrophilicity index of Ag_n–DNA/WC complexes have also been discussed.     

Influence of outer membrane c‐type cytochromes on particle size and activity of extracellular nanoparticles produced by Shewanella oneidensis

The metal‐reducing bacterium Shewanella oneidensis is capable of reducing various metal(loid)s and produces nanoparticles (NPs) extracellularly, in which outer membrane c‐type cytochromes (OMCs) have been suggested to play important roles. The objective of this study was to investigate the influence of the OMCs, that is, MtrC and OmcA, on the size and activity of the extracellular silver NPs (AgNPs) and silver sulfide NPs (Ag₂S NPs) produced by S. oneidensis MR‐1. We found that (i) the lack of OMCs on S. oneidensis cell surface decreased the particle size of the extracellular biogenic AgNPs and Ag₂S NPs; (ii) the biogenic AgNPs from the mutant lacking OMCs showed higher antibacterial activity; and (iii) the biogenic Ag₂S NPs from the mutant lacking OMCs exhibited higher catalytic activity in methylviologen reduction. The results suggest that it may be possible to control particle size and activity of the extracellular biogenic NPs via controlled expression of the genes encoding surface proteins. In addition, we also reveal that in extracellular biosynthesis of NPs the usually neglected non‐cell‐associated NPs could have high catalytic activity, highlighting the need of novel methods that can efficiently retain extracellular NPs in the biosynthesis processes. Biotechnol. Bioeng. 2013; 110: 1831–1837. © 2013 Wiley Periodicals, Inc.     

All‐Printed,Stretchable Zn‐Ag2O Rechargeable Battery via Hyperelastic Binder for Self‐Powering Wearable Electronics

While several stretchable batteries utilizing either deterministic or random composite architectures have been described, none have been fabricated using inexpensive printing technologies. In this study, the authors printed a highly stretchable, zinc‐silver oxide (Zn‐Ag₂O) battery by incorporating polystyrene‐block ‐polyisoprene‐block ‐polystyrene (SIS) as a hyperelastic binder for custom‐made printable inks. The remarkable mechanical properties of the SIS binder lead to an all‐printed, stretchable Zn‐Ag₂O rechargeable battery with a ≈2.5 mA h cm^?2 reversible capacity density even after multiple iterations of 100% stretching. This battery offers the highest reversible capacity and discharge current density for intrinsically stretchable batteries reported to date. The electrochemical and mechanical properties are characterized under different strain conditions. The new stress‐enduring printable inks pave ways for further developing stretchable electronics for the wide range of wearable applications.     

The uptake of silver ions by Escherichia coli K12: toxic effects and interaction with copper ions

Summary Growth of Escherichia coli in chloridefree medium in batch culture is inhibited completely at concentrations of AgNO₃ greater than 2.5x10^-6 M. Incubation of non-growing cells in HEPES buffer (pH 7.4) at increasing levels of Ag⁺ results in the progressive saturation of two types of binding site. At one site, the Ag⁺ is not released by washing with 0.1 M nitric acid, and is probably intracellular. Silver bound to the second site is released by acid-washing, but not by buffer washing, and is assumed to be surface-bound. The amounts of Ag⁺ taken up from solution at the two sites is 1.6x10^-7 and 4.6x10^-7 mol (mg dry weight)^-1, respectively. Total accumulation of silver is 67 mg (g dry weight)^-1, similar to literature values found for silver-resistant bacteria. Binding of Ag⁺ at intracellular sites (observed at low [Ag⁺]) appears to be independent of pH. Addition of AgNO₃ to growing cells in mid-exponential phase of growth in concentrations that will inhibit growth results in substantially decreased accumulation of silver. Growth yield in chemostat culture is diminished in the presence of added Ag⁺, but this effect is moderated by added Cu²⁺, which may protect copper sites from Ag⁺ or compete with Ag⁺ for other sites at which Ag⁺ exerts toxic effects. Very small amounts of Cu²⁺ are found in cell samples from the chemostat compared to the substantial amounts of Ag⁺ taken up, but uptake of Cu²⁺ is decreased at higher [Ag⁺]/[Cu²⁺]ratios.     

Nuclear fast red‐based colorimetric sensors for sensitive and selective detection of Ag ions

The reduction of nuclear fast red (NFR) stain by sodium tetrahydroboron was catalyzed in the presence of silver ions (Ag⁺). The fluorescence properties of reduced NFR differed from that of NFR. The product showed fluorescence emission at 480 nm with excitation at 369 nm. Furthermore, the fluorescence intensity of the mixture increased strongly in the presence of Ag⁺ and Britton–Robinson buffer at pH 4.78. There was a good linear relationship between increased fluorescence intensity (ΔI) and Ag⁺ concentration in the range 5.0 × 10^?9 to 5.0 × 10^?8 M. The correlation coefficient was 0.998, and the detection limit (3σ/k) was 1.5 × 10^?9 M. The colour of the reaction system changed with variation in Ag⁺ concentration over a wide range. Based on the colour change, a visual semiquantitative detection method for recognition and sensing of Ag⁺ was developed for the range 1.0 × 10^?8 to 5.0 × 10^?4 M, with an indicator that was visible to the naked eye. Therefore, a sensitive, simple method for determination of Ag⁺ was developed. Optimum conditions for Ag⁺ detection, the effect of other ions and the analytical application of Ag⁺ detection of synthesized sample were investigated.     

Control of in vitro rooting and plant development in Corymbia maculata by silver nitrate, silver thiosulfate and thiosulfate ion

Plant regeneration and transformation in vitro is often improved by adding silver ion (Ag⁺) to the culture media as AgNO₃ or silver thiosulfate (STS). Ag⁺ reacts with substances to form insoluble precipitates, while thiosulfate (S₂O₃ ²⁻) interferes with these reactions. We studied the implications of silver precipitation and S₂O₃ ²⁻ in the medium for culture development by (1) examining formation of Ag⁺ precipitates from AgNO₃ versus STS in agar gels and their possible dependence on agar type; (2) comparing Corymbia maculata culture responses to AgNO₃ and STS and determining which better suits control of culture development; (3) clarifying whether STS-dependent alterations in culture development are due to Ag⁺ alone or also to a separate influence of S₂O₃ ²⁻. Silver precipitates appeared in aqueous gels of four agar brands supplemented with AgNO₃, but not in Phytagel^™, which remained transparent. No precipitation was observed in gels with STS. Indole-3-butyric acid (IBA)-mediated adventitious root induction and shoot growth were higher in C. maculata shoot tips cultured on gels with STS versus AgNO₃ (6–25 μM Ag⁺). IBA-treated shoot tips exhibited enhanced adventitious root regeneration, accelerated root elongation, increased frequency of lateral root formation, and stimulated shoot growth mediated by 100–250 μM sodium thiosulfate (Na₂S₂O₃) in medium without Ag⁺. The potency of S₂O₃ ²⁻ in facilitating culture development has never been recognized. It is inferred that superiority of STS in stimulating multiple responses of C. maculata culture results from sustained biological activity of Ag⁺ through prevention of its precipitation, and from impact of S₂O₃ ²⁻ on cell differentiation and growth.     

Silver ions induce a rapid Ca2+ release from isolated intact bovine rod outer segments by a cooperative mechanism

Summary Micromolar concentrations of silver ion activate large Ca²⁺ fluxes across the plasma membrane of intact rod outer segments isolated from bovine retinas (intact ROS). The rate of Ag⁺-induced Ca²⁺ efflux from intact ROS depended on the Ag⁺ concentration in a sigmoidal manner suggesting a cooperative mechanism with a Hill coefficient between 2 and 3. At a concentration of 50 m Ag⁺ the rate of Ca²⁺ efflux was 7×10⁶ Ca²⁺/outer segment/sec; this represents a change in total intracellular Ca²⁺ by 0.7mm/outer segment/sec. Addition of the nonselective ionophore gramicidin in the absence of external alkali cations greatly reduced the Ag⁺-induced Ca²⁺ efflux from intact ROS, apparently by enabling internal alkali cations to leak out. Adding back alkali cations to the external medium restored Ag⁺-induced Ca²⁺ efflux when gramicidin was present. In the presence of gramicidin, Ag⁺-induced Ca²⁺ efflux from intact ROS was blocked by 50 m tetracaine orl-cis diltiazem, whereas without gramicidin both blockers were ineffective. Bothl-cis diltiazem and tetracaine are blockers of one kinetic component of cGMP-induced Ca²⁺ flux across ROS disk membranes. The ion selectivity of the Ag⁺-induced pathway proved to be broad with little discrimination between the alkali cations Li⁺, Na⁺, K⁺, and Cs⁺ or between Ca²⁺ and Mg²⁺. The properties of the Ag⁺-induced pathway(s) suggest that it may reflect the cGMP-dependent conductance opened in the absence of cGMP by silver ions.     

Bimutation breeding of Aspergillus niger strain for enhancing β-mannanase production by solid-state fermentation

A parent strain Aspergillus niger LW-1 was mutated by the compound mutagenesis of vacuum microwave (VMW) and ethyl methane sulfonate (EMS). A mutant strain, designated as A. niger E-30, with high- and stable-yield β-mannanase was obtained through a series of screening. The β-mannanase activity of the mutant strain E-30, cultivated on the basic fermentation medium at 32 °C for 96 h, reached 36,675 U/g dried koji, being 1.98-fold higher than that (18,501 U/g dried koji) of the parent strain LW-1. The purified E-30 β-mannanase, a glycoprotein with a carbohydrate content of 19.6%, had an apparent molecular weight of about 42.0 kDa by SDS–PAGE. Its optimal pH and temperature were 3.5 and 65 °C, respectively. It was highly stable at a pH range of 3.5–7.0 and at a temperature of 60 °C and below. The kinetic parameters K_m and V_max, toward locust bean gum and at pH 4.8 and 50 °C, were 3.68 mg/mL and 1067.5 U/mg, respectively. The β-mannanase activity was not significantly affected by an array of metal ions and EDTA, but strongly inhibited by Ag⁺ and Hg²⁺. In addition, the hydrolytic conditions of konjak glucomannan using the purified E-30 β-mannanase were optimized as follows: konjak gum solution 240 g/L (dissolved in deionized water), hydrolytic temperature 50 °C, β-mannanase dosage 120 U/g konjak gum, and hydrolytic time 8 h.