Selective alginate degradation by marine bacteria associated with the algal genusSargassum

Summary Alginase-secreting bacteria associated with actively growing tissues of the marine Phaeophyta speciesSargassum fluitans andS. natans have been isolated and evaluated for their ability to degrade alginate (ALG), carboxymethylcellulose, and agar. Of seven isolates selected for their ability to grow on 2% agar containing 1% sodium alginate, none were able to grow on either 2% agar or 2% agar supplemented with 0.1% carboxymethylcellulose. Two of these with fermentative potential, i.e., ALG-A and ALG-G, showed selective activities with respect to their ability to degrade native alginate and/or take up the products resulting from alginate degradation. The ALG-A isolate was able to rapidly degrade native alginate with the generation of a stable polymer fraction and small oligouronides, most of which were dissimilated for growth. The ALG-G isolate was able to completely degrade native alginate with the accumulation of significant quantities of unsaturated dimeric and trimeric oligouronides. A limit polymer was generated from the action of a polymannuronan-specific extracellular alginate lyase purified from exponential cultures of the ALG-A organism. This product proved to be an effective substrate for the alginate lyase activity obtained from the medium of exponential phase cultures of the ALG-G isolate, and upon incubation with concentrated and dialyzed ALG-G medium was converted to the products that were observed to accumulate in the medium of the ALG-G isolate grown on native alginate. These organisms represent examples of the microflora associated with actively growingSargassum tissues, each with a selective ability to degrade and dissimilate the biomass of the marine brown algae.     

On the properties of agar gel containing ionic and non-ionic surfactants

Rheological and thermal properties of agar sol and gel in presence of various cationic, anionic and non-ionic surfactants are reported. The agar used was from the red seaweed Gelidiella acerosa. The gel strength, viscosity, rigidity (G'), gelling temperature and melting temperature were observed to decrease in presence of non-ionic surfactants whereas these were enhanced in presence of ionic surfactants. TGA studies showed that 1.5% agar gels containing non-ionic surfactants lose water at a lower temperature than the control agar gel whereas gels containing ionic surfactants hold on to water more tenaciously. DSC studies, on the other hand, show that the gel to sol transition occurs at lower temperatures in presence of non-ionic surfactants and at higher temperature in presence of ionic surfactants when compared with the control gel. The non-ionic surfactants, Triton X-100 and Brij 35, enabled relatively concentrated agar extractive to be filtered readily, as a result of which water usage in the process could be reduced by 50%. The surfactant was subsequently removed through freeze-thaw operations to restore the gelling capacity of the agar. The finding that 0.3-0.4% (w/v) sodium lauryl sulfate (SLS) lowers the sol-gel transition temperature from 41 to 36 degrees C without adversely affecting gel strength is another useful outcome of the study that may enable better formulations of bacteriological agar to be prepared.     

Influence of alkali treatment on agar from Gracilaria cornea from Yucatán, México

The effect of alkali treatments on the yield, rheological and chemical properties of agar from Gracilaria cornea growing along the Yucatáncoast were studied in order to evaluate its potential for industrial use inan attractive economic standpoint. Alkali treatment was carried out with NaOH concentrations of 0.5%, 1%, 3% and 5% in a water bath at 80, 85 and 90 °C. Agar yield, gel strength, gelling and melting temperatures, sulphate, 3,6-anhydro-galactose and ash content weredetermined. The different combinations of NaOH concentration and treatment temperature strongly influenced agar characteristics. There was a variation in the agar content for all NaOH treatments and temperature combinations, ranging between 14.5% to 22.1%. Although the yields obtained for 0.5% NaOH at all temperatures and 1% NaOH at 80 and 85°C were higher than those required by the industry, the physical and chemical characteristics of the agar were similar to those obtained fornative agar from the same species. The gel strengths, sulphate content and gelation hysteresis obtained with agar from the 1% NaOH treatment at 90 °C are in the range required by the food industry. Treatments with 3% and 5% NaOH at all temperatures improved significantly the agar quality giving higher gel strengths (974–1758 g cm ^-2) than those reported for other Gracilaria species. This revised version was published online in August 2006 with corrections to the Cover Date.     

Effects of seasons on the chemical structure and gel strength of Gracilaria pseudoverrucosa agar (Gracilariaceae, rhodophyta)

The seasonal effects on the chemical structure and rheological properties of Gracilaria pseudoverrucosa agar have been investigated using a sequential solvent extraction, ¹³C NMR and infrared spectroscopy, and gel strength measurements. The results showed that agar enriched in precursor to the agarobiose repeat unit were obtained from algae collected in summer. In contrast, algae collected in winter contained agar molecules richer in alkali-stable sulfate groups attributed in part to -galactose-4-sulfate. A similar total concentration of 6-O-methylated agarobiose repeat units was present in the agar from both algal samples but the distribution of the methylated disaccharide varied in the fractions. Agar fractions from the summer-collected sample had higher gel strength than those of the winter ones. Alkali treatment markedly improved the gel strength of the agar from the summer harvested seaweed. Different gel strengths were observed for the native and alkali-treated agar fractions extracted from the same algal sample and a gel strength comparable to that obtained for a commercial bacteriological grade agar was obtained from the alkali-treated 40% ethanol extract agar from the summer collected alga. The chemical and rheological variations due to seasonal changes are interpreted as reflecting the ratio of actively-growing (young) to resting (old) tissue in the alga and are proposed to represent a type of ‘secondarization’ of the algal cell-wall.     

Evaluation of agar and agarose gels for studying mechanical impedance in rice roots

Agar and agarose gels were evaluated as systems to mechanically impede roots of rice (Oryza sativa L.). Two-layer gels were used so that seedlings established in a layer of weak gel (0.35% weight/volume) and then grew downwards to encounter a treatment gel of up to 5.0% (w/v). Agarose gels were stronger than agar gels of the same concentration, reaching a maximum penetrometer resistance of 1.2 MPa at a concentration of 5.0%, compared to 0.3 MPa with agar. The 5.0% agar gel stimulated elongation of the seminal axis by 40% in seedlings of variety TN1 (compared with elongation in the 0.2% gel), but decreased it by 15% in the variety Lac 23. Although increasing agarose concentration decreased seminal axis elongation in both varieties, the seminal axis did not reach the lower layer of treatment gel when the concentration of the treatment gel was greater than 2.0%. The decreased root elongation was therefore a non-mechanical inhibition. In experiments conducted using a different batch of agarose, these inhibitory effects were not seen and strong agarose gels stimulated seminal axis elongation. It was concluded that the agar and agarose gel systems studied were unsuitable for studying the effect of mechanical impedance on the elongation of rice roots and that great care should be taken in interpreting the results of experiments using gels as a growth medium. This revised version was published online in June 2006 with corrections to the Cover Date.     

Densitometric determination of nucleic acids in gels after electrophoresis

A technique for the quantitative determining of nucleic acids after electrophoresis by double-wave densitometry in UV spectrum by scanning agar gel along both axes was developed. Optical characteristics of agar and acrylamide-agar gels are given. The range of quantities measured is 6 divided by 30 micrograms of DNA per gel; the standard deviation adjusted to 1 microgram is less than +/- 3%.     

Diffusion of sucrose and dextran through agar gel membranes

Mass transfer limitations severely impede the performance of bioreactions involving large molecules by gel-entrapped microorganisms. This paper describes a quantitative investigation of such diffusional limitations in agar gel membranes. Sucrose and commercial dextran fractions with (weight-average) molecular weights ranging from 10,000 to 2,000,000 Da were used as standard diffusants. For all tested solutes but sucrose, the values of the agar/water partition coefficients highlighted steric hindrance at the entrance of the membrane pores. The effective diffusivity of sucrose in agar was similar to that in water. All dextran fractions, however, displayed restricted diffusion in the agar membranes. Their effective diffusivities were a decreasing function of the agar content of the gel membrane (0.5, 1.0, or 1.5% w/v). The effective diffusivity in a given membrane decreased as the molecular weight of the diffusing molecule increased. T500 (ucbar|M_w = 470,000 Da) and ucbar|M_w = 1,950,000 Da) fractions were unable to diffuse through 1.0 or 1.5% agar membranes. The diffusion data did not agree with the classical (Renkin) model for a hard sphere diffusing through a cylindrical pore. These results are discussed in terms of gel and diffusant characteristics.     

Effects of phosphate and nitrate supply on productivity,agar content and physical properties of agar ofGracilaria strain G-16S

Gracilaria strain G-16S was cultured in various phosphorus (P) supply rates with low or high nitrogen (N) supply to determine the effects of nutrient supply on its productivity, agar content and physical properties of the agar. Productivity was reduced after four weeks of growth in zero P supply as plants reached 0.07% P tissue content (critical level), with fragmentation of these plants by six weeks (0.05% P; minimum viable level). Native agar content was higher in low P and high N, or low N conditions. Agar content appeared to increase with decreasing P under high N supply. This increase was not apparent with alkali treatment prior to extraction. Agar gel strength was greatly increased by alkali treatment. The highest gel strengths were obtained under high N supply at all P supply rates except zero P, and under low N supply at 12 M P week^–1. Native agar gel strengths showed a similar pattern on a lower scale. Melting temperatures were higher in agars with higher gel strengths. Dynamic gelling temperatures were generally high for alkali-treated agar, with agar from plants grown in zero P supply showing a slightly elevated gelling temperature. Melting and gelling temperatures of native agars with the highest gel strengths were in the same range as bacteriological agar. These results show that P and N supply affects productivity, agar content and agar physical properties, but the tradeoffs between a slightly higher agar quantity under nutrient limitation and higher agar quality under nutrient-replete conditions seem to favor the latter.     

Enumeration of cellulolytic anaerobic bacteria from the bovine rumen: Comparison of three methods

Three methods—the most probable number technique, a cellulose agar overlay on basal carbohydrate plates, and carboxymethylcellulose in basal carbohydrate plates—were compared for ease of preparation, interpretation of results, and agreement in estimation of size of the cellulolytic bacterial population in digesta samples from the rumen. The most probable number method yielded consistent detection of cellulose hydrolysis in liquid medium but required at least a 10-day incubation, and its mean was associated with wide 95% confidence intervals. The cellulose overlay method was the least consistent, and zones of hydrolysis often were difficult to see. The carboxymethylcellulose method was the easiest method for preparation and required only a 2-day incubation. The three methods estimated the same population size (all within one-half log unit of each other), but the carboxymethylcellulose method had the lowest coefficient of variation.     

Mechanism of Enhancement of Virus Plaques by Cationic Polymers

It has been assumed that plaque enhancement by cationic polymers is due to their binding of sulfated polysaccharides in agar. However, viruses that are enhanced by cationic polymers, diethylaminoethyl-dextran, and protamine were found not to be inhibited by polyanions in agar under the usual overlay conditions. In the case of adenovirus, enhancement by protamine seems to be due to the protamine serving as a source of arginine; enzymes released from the cultured cells digest the protamine and provide a reservoir of arginine for the cells. Other viruses (herpes and echovirus types 3, 4, 5, and 6) known to be susceptible to agar inhibitors were found to be enhanced by cationic polymers even under starch gel and methylcellulose overlays, which are free of polyanions. Since cationic polymers enhance the diffusion of virus through agar or starch gel, plaque enhancement seems to be the result of the gel becoming positively charged so that viruses can move effectively through them. The observation that starch gel and methylcellulose enhance plaque formation with viruses known to be inhibited under agar was also reinvestigated. When the consistency of the agar gel was reduced to the same viscosity of starch gel and methylcellulose overlays, the same plaque counts and sizes were observed under all three overlays.     

Immunodiffusion method for detection of type A Clostridium botulinum.

A simple gel immunodiffusion agar procedure was developed for detecting toxigenic strains of Clostridium botulinum type A. The method consisted of overlaying colonies grown on thin-layer tryptone-peptone-glucose-yeast extract agar with gel diffusion agar containing desired levels of C. botulinum type A antitoxin. Concentric precipitin zones formed around colonies of C. botulinum type A. Strains of C. botulinum type A were detected by this procedure. However, C. botulinum type B reacted to a lesser degree with this system. No reaction was noted with types E, F, Langeland, F8G, Clostridium perfringens, or with strains of nontoxigenic Clostridium sporogenes. Thickness of the plating medium, incubation time and temperature, environmental growth conditions, and levels of both agar an antitoxin were important factors affecting the efficiency of the procedure, whereas the age of the culture (used as inoculum) was not critical. Thin agar medium (5 ml per plate [15 by 100 mm]) containing 1.5% agar gave consistent results, but more agar limited diffusion, and lower levels encouraged spreaders. The optimal concentration of antitoxin incorporated in to the gel diffusion agar overlay was 1.2 IU/ml gel diffusion agar. Rabbit type A antitoxin prepared with purer immunizing agent gave similar reactions. The addition of type A antitoxin in tryptone-peptone-glucose-yeast extract agar medium before inoculation with type A C. botulinum showed promising results.     

Immunodiffusion method for detection of type A Clostridium botulinum

A simple gel immunodiffusion agar procedure was developed for detecting toxigenic strains of Clostridium botulinum type A. The method consisted of overlaying colonies grown on thin-layer tryptone-peptone-glucose-yeast extract agar with gel diffusion agar containing desired levels of C. botulinum type A antitoxin. Concentric precipitin zones formed around colonies of C. botulinum type A. Strains of C. botulinum type A were detected by this procedure. However, C. botulinum type B reacted to a lesser degree with this system. No reaction was noted with types E, F, Langeland, F8G, Clostridium perfringens, or with strains of nontoxigenic Clostridium sporogenes. Thickness of the plating medium, incubation time and temperature, environmental growth conditions, and levels of both agar an antitoxin were important factors affecting the efficiency of the procedure, whereas the age of the culture (used as inoculum) was not critical. Thin agar medium (5 ml per plate [15 by 100 mm]) containing 1.5% agar gave consistent results, but more agar limited diffusion, and lower levels encouraged spreaders. The optimal concentration of antitoxin incorporated in to the gel diffusion agar overlay was 1.2 IU/ml gel diffusion agar. Rabbit type A antitoxin prepared with purer immunizing agent gave similar reactions. The addition of type A antitoxin in tryptone-peptone-glucose-yeast extract agar medium before inoculation with type A C. botulinum showed promising results.     

Determination of Trace Element Stability in Sediments Using Redox Gel Probes: Probe Construction and Theoretical Performance

A simple and inexpensive technique is described that can be used to assess the stability of redox-sensitive compounds in the sediments of wetlands and other shallow water environments. In this method, solid redox-sensitive compounds, such as manganese dioxide (MnO 2 ), are incorporated into agar gels held in rigid plastic holders. One surface of the gel remains exposed along the length of the resulting probe. The probes are pushed vertically into sediments and are left in situ for a period of time (days to weeks), after which they are visually inspected and chemically analyzed. The diffusion of nonreactive solutes (e.g., sulfate) in 2% (wt/vol) agar was unaffected by the presence of immobilized MnO 2 particles. The rate of dissolution of particulate MnO 2 in agar gels in the presence of an external diffusing reductant (L-ascorbic acid) could be quantified by digital analysis of pixel density on gel images. Redox gel probes incubated in the sediment of a wetland built to remove manganese from circumneutral pH coal mine drainage demonstrated different patterns of depth-dependent MnO 2 stability along a 15-m transect. MnO 2 gel probe results were consistent with data obtained using sediment cores and porewater diffusion samplers.     

A comparison of rapid electrophoretic and chromatographic methods for the investigation of common histological dyes

Summary The compositions of fifty-nine common histological dyes, as well as duplicate samples of several dyes from different suppliers, have been studied by agar gel electrophoresis, agarose gel electrophoresis, paper electrophoresis, paper chromatography and thin layer chromatography. Tables are presented to show the number of components present in each dye as disclosed by the different methods; the cases where duplicate samples were available are summarised in a separate table.On the basis of effectiveness and convenience agar gel electrophoresis and thin layer chromatography were by far the best methods. The Chromatographic method was of slightly wider applicability but as electrophoretic methods gave information on dye charge, agar gel electrophoresis was the best single method.     

Optimization of the yield and quality of agar from Gracilariopsis lemaneiformis (Gracilariales) from the Gulf of California using an alkaline treatment

The effect of several alkali treatments on the yield, gel strength, rheology, and chemical characteristics (quality) of the agar obtained from Gracilariopsis lemaneiformis from the Gulf of California was analyzed using different alkali concentrations, temperatures and treatment times. In the first stage of the experiment, all treatments lasted 60 min and the NaOH concentrations (2.5, 3.0, 4.0, 5.0, 6.0%) and temperature (80, 90, 100°C) varied. At constant time, temperature played the predominant role, promoting an increase in agar gel strength. Based on the best treatment conditions found (4% and 5% NaOH, and 90°C and 100°C temperature), in the second stage different treatment times (15, 30, 60, 90, 120 min) were used. Since agar yields were not significantly different among temperatures and times, the optimal conditions to obtain best quality agar were those providing the highest gel strength. Treatment time played an important role in increasing gel strength. Maximum gel strength (Nikan, 954 g cm⁻²) was obtained with 5% NaOH at 100°C after 90 min of treatment, though these conditions resulted in an agar yield reduction of 25.5% relative to native agar. This treatment proved to efficiently yield G. lemaneiformis agar that will meet the commercial quality requirements regarding gel strength, 3,6 anhydrogalactose and sulfate content, as well as rheology and hysteresis. Enrique Hernández-Garibay holds a CONACyT scholarship.     

Isolation of eukaryotic ribosomal proteins. Purification and characterization of the 60 S ribosomal subunit proteins La, Lb, Lf, P1, P2, L13', L14, L18', L20, and L38

The proteins of the large subunit of rat liver ribosomes were separated into seven groups by stepwise elution from carboxymethylcellulose with LiCl at pH 6.5. Ten proteins (La, Lb, Lf, P1, P2, L13', L14, L18', L20, and L38) were isolated from three groups (A60, B60, and D60) by ion exchange chromatography on carboxymethylcellulose and DEAE-cellulose, and by filtration through Sephadex. The amount of protein obtained varied from 0.3 to 3.8 mg. Two of the proteins (La and L18') had no detectable contamination; the impurities in the others were not greater than 8%. The molecular weight of the proteins was estimated by polyacrylamide gel electrophoresis in sodium dodecyl sulfate; the amino acid composition was determined. Several additional acidic proteins were identified: P1a and P1b are phosphorylated derivatives of P1; P2a, P2b, and P2c are phosphorylated derivatives of P2. P1 and P2 are distinct proteins but both have large amounts of alanine (20.4 and 17.5 mol %).     

The agar component of the red seaweed Gelidium purpurascens

Chemical composition and rheological properties of agar isolated from Gelidium purpurascens, the agar after alkaline treatment, and a commercial agar are presented. The agar and alkali-treated agar gave weaker gels, as measured with an Instron 1122, than those of commercial agar. Xylose, glucose and glucuronic acid in the agar were removed together with 86% of the nitrogen content on alkaline treatment, indicating occurrence of these residues as carbohydrate-protein complexes. Sequential extraction of the alga accounted for low yields of agar as losses incurred on ethanol precipitation. Acid treatment of the residue from exhaustive aqueous extraction of the alga liberated a further 10% agar with increased gel strengths despite increased glucose inclusion, suggesting a lack of involvement of these ‘contaminant’ carbohydrate-protein residues in helix coil formation during gelling.     

New insights in agar biorefinery with arylsulphatase activities

Agar is a major gelling agent used both in food and pharmaceutical applications. Traditional purification of agar is generally performed by sequential time consuming chemical and/or physical steps, leading to both poor recovery yields and low productivities. As a consequence, only 30% of the amount of agar produced is actually available under purified form to feed the world market.The current limiting factor for purification is the presence of sulphated compounds such as sulphated-agaropectin, which strongly affect the technological properties of the agar gel such as gel strength, melting and fusion temperatures and electroendosmosis.In this context, this communication aims at discussing about the development of a biorefining agar purification approach which allows overcoming the current limitations associated with traditional purification methods. More specifically, this article focuses on the potential role of arylsulphatases in agar purification processes to reduce the number of purification steps and to improve recovery yields.This review first presents the global gelling agents market before focusing on agar characteristics and production processes. Then, after a brief reminder of the sulphur metabolism, the roles, classes and properties of the different arylsulphatases are described to draw perspectives on their integration in current or new agar production processes.     

Polysaccharides from the red seaweed Gracilaria dura (Gracilariales, Rhodophyta)

The yield and physical and chemical properties of agars from Gracilaria dura (C. Agardh) J. Agardh, harvested in Thau lagoon (Mediterranean sea, France), were investigated. The agar yield ranged from 32% to 35%. Gel strength of agar ranged from 263 to 600 g cm(-2), with the maximum observed in October. A positive correlation was found between agar yield and gel strength (r = 0.82; P < 0.01). The gelling temperature followed the same pattern of gel strength and also showed higher value in October (43 degrees C). The nitrogen content varied from 1.04+/-0.60% (June) to 4.70+/-0.01% (October). A positive correlation was noted between nitrogen content and gel strength (r = 0.77; P < 0.05). The 3,6-anhydrogalactose content ranged from 0.70 to 0.84 and showed monthly significant differences (P < 0.05). There was a positive correlation between 3,6-anhydrogalactose content and gel strength. The values of sulfate content were relatively constant during the studied period and no significant differences were observed. The relative high gel strength indicates that this species may be considered as source of agar for commercial use.     

Agar quality of commercial agarophytes from different geographical origins: 1. Physical and rheological properties

Six economically important species ofGracilaria, from a number of commercial sources around the world, andGracilariopsis lemaneiformis, collected from two Japanese localities, were used as the sources of raw material for the evaluation of agar quality. Agar-agar was extracted by pretreatment with various concentratrions of NaOH (0%, 3%, 5%, 7%, 10%) incubated at 80 °C for 2 h. Agar yield, viscosity, dynamic gelling and melting temperature and gel texture were determined for 1.5% agar gels. The highest agar yield was obtained fromG. gracilis from Argentina (39.5%), while the lowest was from BrazilianG. gracilis (13.37%). Dynamic gelling temperature was highest in the agar fromG. gracilis from Turkey (59 °C) and lowest in the non-alkali treated agar isolated fromG. edulis from Indonesia (46 °C). Melting temperature ranged from 96 °C in the agars from the JapaneseGracilariopsis andG. chilensis from Chile to 69 °C in the non-alkali treated agar fromG. edulis from Indonesia. In general, all species produced an agar with high gel strength after treatment with 5% NaOH, except forG. chilensis and the twoGracilariopsis species, which produced an agar with high gel strength after treatment with 3, 7 and 10% NaOH. The highest gel strength (2056 ± 13.6 cm^–2) and hardest gel (261 ± 19.89 g mm^–2) were obtained fromG. lemaneiformis from Japan (Oita Prefecture) after treatment with 7 and 10% NaOH respectively. The lowest gel strength (351 ± 93 cm^–2) was obtained fromG. gracilis from Brazil after treatment with 3% NaOH. The softest gel (66.31 ± 9.63 g mm^–2) was isolated fromG. tenuistipitata from China, after treatment with 3% NaOH. The most flexible gel (11.62 ± 0.31 g mm^–2 × 10²) was obtained fromG. chilensis from Chile after treatment with 3% NaOH.Author for correspondence