Influence of physiological factors on the lysis effect of Cytophaga on the red microalga Rhodella reticulata

The influence of different factors on the lysis of the red microalga, Rhodella reticulata, by Cytophaga sp. LR2 was studied. The pathogenic bacterial strain was more resistant than the alga to the physiological parameters studied, which assured long-term survival of bacteria in algal cultures. Cytophaga sp. LR2 infected R. reticulata at temperatures between 15 and 30 degrees C, in the illuminated as well as the non-illuminated cultures, at pH values between 5.0 and 9.0, and in the presence of NaCl and CaCl2 in the culture medium. SEM showed a different morphology of the bacteria in algal cultures from those of axenic cultures of Cytophaga. Observations of specific associations between algal and bacterial cells revealed that the role of the slime extrusions on the bacterial surface was attachment of Cytophaga to algal cells, and that their clumping leads to rapid lysis.     

Extra- and intra-cellular lytic effects of Cytophaga sp. LR2 on the red microalgae Rhodella reticulata

AIMS: To evaluate the lytic activities of crude enzymes from Cytophaga sp. LR2 on Rhodella reticulata cells and isolated algal polysaccharide. METHODS AND RESULTS: The Cytophaga compartment was separated after centrifugation in a cell suspension for 30 min at 18,000 g. The extracellular enzyme was obtained from the supernatant and the intracellular from the pelleted cells after sonication and removal of debris. Algal cells were incubated with extra- or intracellular preparations and sowed onto agar medium. The suppressive effect of the extracellular enzyme on colony-forming units was found to be almost twice as high. The result was still more pronounced when treated cells had been shocked osmotically before seeding. Saccharolytic activity was evaluated by changes in the reducing sugars in the media. Concerning isolated algal polysaccharide, the reducing power of the two bacterial preparates was relatively low. A combined fraction showed the highest lytic activity. Using native and SDS electrophoresis some relation between the prevalence of the extra and intracellular protein patterns was registered. Two of the common components' molecular weight masses of 50 and 21 kDa were found to be reproducible in native- and SDS-containing gel. CONCLUSIONS: Cytophaga sp. LR2 produce extra- and intracellular enzymes active in destroying Rhodella cultures. The agents excreted in the medium are more effective.We suppose that two or three different classes of enzymes are involved in the lysis process. The comparative electrophoresis in this case shows the protein components with predictable functions. SIGNIFICANCE AND IMPACT OF THE STUDY: Combining different simple and reproducible approaches to identify the lytic capability of Cytophaga sp. LR2 on R. reticulata.     

A bacterial pathogen of Rhodella reticulata

A bacterium was isolated which caused disease in a laboratory culture of the red alga, Rhodella reticulata. The organism was an aerobic Gram-negative rod, aflagellate andpigmented. The absorption maximum of the pigments in methanol was 460 nm. The bacteriumshowed hydrolytic activity towards agar and produced extracellular agarase. The organismutilized monosaccharide constituents of the polysaccharide of R. reticulata , as well asthe whole polysaccharide of alga, as a sole carbon source. The bacterium was identified as Cytophaga sp. LR₂.     

Effect of Bacteria Associated with the Green Alga Ulva reticulata on Marine Micro- and Macrofouling

The green alga Ulva reticulata (Forsskal) is often free from biofouling in Hong Kong waters. An early study indicated that bioactive substances from this alga inhibit settlement of the polychaete Hydroides elegans (Haswell). It is also predicted that epibiotic bacteria protect this alga from micro- and macrofouling. In this study, bacterial strains from the surface of U. reticulata were isolated and their inhibitive activities on micro- and macrofouling assayed. The strains were identified by 16S rRNA analysis as belonging to the genera Alteromonas , Pseudoalteromonas and Vibrio . There was no significant effect of these strains or their extracts (aqueous and ethanol) on the growth of five Vibrio strains isolated from natural biofilm. Two bacterial strains ( Alteromonas sp. and Vibrio sp. 3) were non-toxic to the benthic diatom Nitzschia paleacea (Grunow) while the other five strains caused a low level of mortality. No one bacterial strain was toxic to the larvae of H. elegans . Aqueous extract of one of the isolated bacterial species, i.e. Vibrio sp. 2, significantly ( p <0.00001) inhibited the settlement and metamorphosis of H. elegans larvae. The putative antifouling compounds have a molecular weight of >100 kD. On the other hand, biofilm of Pseudoalteromonas sp. 2 and aqueous extract of Vibrio sp. 2 suppressed the settlement of larvae induced by 3-isobutyl-1-methylxanthine (IBMX). Other epibiotic bacteria and their extracts had neither inhibitive nor inductive effects on larval settlement of H. elegans . The results indicate that the antifouling mechanism of U. reticulata may be dependent not only on materials from the macroalga itself but also on the epibiotic bacteria on the algal surface.     

Lysis of a red-tide causing alga,Alexandrium tamarense,caused by bacteria from its phycosphere

There are bacteria coexisting in xenic cultures of Alexandrium tamarense, a red-tide causing alga. However little is known concerning the interactions between the alga and the bacteria in its phycosphere. The objective of the current study was to determine the effect of the bacteria in its phycosphere on the growth of the alga. We added one percent (v/v) Zobell 2216E medium to A. tamarense culture to alter bacterial growth and the results showed that algal cells were all lysed within 14 h. After adding the medium, both the abundance and the extracellular enzyme activity of the bacteria increased by 50–100 times from the 4th to the 10th hour which resulted in lysis of the algae. The 16S rRNA gene fragments of the bacteria were amplified from the DNA extracted from A. tamarense cultures and analyzed by denaturing gradient gel electrophoresis and sequencing. The structure of the bacterial community in phycosphere changed significantly during algal lysis. Two bacterial genera, Alteromonas sp. and Thalassobius aestuarii sp. are key factors that caused the lysis, and the β-glucosidase and chitinase produced by the bacteria in the phycosphere could directly cause the lysis. These experiments provide evidence that bacteria in its phycosphere play a key role in the culture of A. tamarense, and may provide insights into the future biocontrol of red-tides.     

Effect of bacterial satellites on Chlamydomonas reinhardtii growth in an algo-bacterial community

The growth characteristics of an algo-bacterial community (Chlamydomonas reinhardtii and bacterial satellites) were studied, as well as the mechanism and patterns of bacterial effect on algae. Four strains of predominant bacteria were isolated and partially characterized. They were assigned to the following taxa: Rhodococcus terrea, Micrococcus roseus, and Bacillus spp. A pure culture of the alga under study was obtained by plating serial dilutions on agarized media with ampicillin. Within the algo-bacterial association, the alga had a higher growth rate (0.76 day(-1)) and yield (60 microg chlorophyll/ml culture) than in pure cultures (0.4 day(-1) and 10 microg chlorophyll/ml culture, respectively). The viability of the algal cells within the association was retained longer than in pure culture. Among the isolated bacterial satellites, strains B1 and Y1, assigned to the species Rhodococcus terrae, had the highest stimulatory effect on algal growth. The culture liquid of bacteria incubated under the conditions not permitting growth stimulated algal growth; the culture liquid of actively growing bacteria had an opposite effect.     

Effect of bacterial satellites on Chlamydomonas reinhardtii growth in an algo-bacterial community

The growth characteristics of an algo-bacterial community (Chlamydomonas reinhardtii and bacterial satellites) were studied, as well as the mechanism and patterns of bacterial effect on algae. Four strains of predominant bacteria were isolated and partially characterized. They were assigned to the following taxa: Rhodococcus terrea, Micrococcus roseus, and Bacillus spp. A pure culture of the alga under study was obtained by plating serial dilutions on agarized media. Within the algo-bacterial association, the alga had a higher growth rate (0.76 day^?1) and yield (60 μg chlorophyll/ml culture) than in pure cultures (0.4 day^?1 and 10 μg chlorophyll/ml culture, respectively). The viability of the algal cells within the association was retained longer than in pure culture. Among the isolated bacterial satellites, strains B1 and Y1, assigned to the species Rhodococcus terrae, had the highest stimulatory effect on algal growth. The culture liquid of bacteria incubated under the conditions not permitting growth stimulated algal growth; the culture liquid of actively growing bacteria had an opposite effect.     

Identification and characterization of potentially algal-lytic marine bacteria strongly associated with the toxic dinoflagellate Alexandrium catenella

The toxic dinoflagellate Alexandrium catenella isolated from fjords in Southern Chile produces several analogues of saxitoxin and has been associated with outbreaks of paralytic shellfish poisoning. Three bacterial strains, which remained in close association with this dinoflagellate in culture, were isolated by inoculating the dinoflagellate onto marine agar. The phenotypically different cultivable bacterial colonies were purified. Their genetic identification was done by polymerase chain reaction amplification of the 16S rRNA genes. Partial sequence analysis suggested that the most probable affiliations were to two bacterial phyla: Proteobacteria and the Cytophaga group. The molecular identification was complemented by morphological data and biochemical profiling. The three bacterial species, when grown separately from phytoplankton cells in high-nutrient media, released algal-lytic compounds together with aminopeptidase, lipase, glucosaminidase, and alkaline phosphatase. When the same bacteria, free of organic nutrients, were added back to the algal culture they displayed no detrimental effects on the dinoflagellate cells and recovered their symbiotic characteristics. This observation is consistent with phylogenetic analysis that reveals that these bacteria correspond to species distinct from other bacterial strains previously classified as algicidal bacteria. Thus, bacterial-derived lytic activities are expressed only in the presence of high-nutrient culture media and it is likely that in situ environmental conditions may modulate their expression.     

Responses of the coastal bacterial community to viral infection of the algae Phaeocystis globosa

The release of organic material upon algal cell lyses has a key role in structuring bacterial communities and affects the cycling of biolimiting elements in the marine environment. Here we show that already before cell lysis the leakage or excretion of organic matter by infected yet intact algal cells shaped North Sea bacterial community composition and enhanced bacterial substrate assimilation. Infected algal cultures of Phaeocystis globosa grown in coastal North Sea water contained gamma- and alphaproteobacterial phylotypes that were distinct from those in the non-infected control cultures 5 h after infection. The gammaproteobacterial population at this time mainly consisted of Alteromonas sp. cells that were attached to the infected but still intact host cells. Nano-scale secondary-ion mass spectrometry (nanoSIMS) showed ∼20% transfer of organic matter derived from the infected ¹³C- and ¹⁵N-labelled P. globosa cells to Alteromonas sp. cells. Subsequent, viral lysis of P. globosa resulted in the formation of aggregates that were densely colonised by bacteria. Aggregate dissolution was observed after 2 days, which we attribute to bacteriophage-induced lysis of the attached bacteria. Isotope mass spectrometry analysis showed that 40% of the particulate ¹³C-organic carbon from the infected P. globosa culture was remineralized to dissolved inorganic carbon after 7 days. These findings reveal a novel role of viruses in the leakage or excretion of algal biomass upon infection, which provides an additional ecological niche for specific bacterial populations and potentially redirects carbon availability.     

Degradation of agarophytic red algal cell wall components by new crude enzyme preparations

Several new crude enzyme preparations were isolated from a marine association of the agarolytic bacterium Cytophaga diffluens and the infusorium Uronema marinum, an axenic culture of Cytophaga diffluens, some species of land micro- and macromycetes adapted to assimilate red algal biomass and from the marine mollusc Littorina littorea. Fungal and mollusc enzyme preparations were shown to have cellulase, xylanase, protease and agarase activities. Fungal agarase activity was revealed only after 3–4 passages of the culture on the medium containing algal biomass. Enzyme preparations from the association and the pure bacterial culture growing on the medium with bactoagar as the sole carbon source contained only agarase activity. The maximum specific agarase activity was found in a preparation from the marine association. The preparations obtained can be used for isolating protoplasts and single cells from red seaweed thalli. This revised version was published online in June 2006 with corrections to the Cover Date.     

Detoxification of high concentrations of trinitrotoluene by bacteria

The ability of the strains-destructors of various aromatic compounds to utilize trinitrotoluene (TNT) up to concentration of 70 mg/1 was shown. An increase in the TNT concentration from 100 to 150 mg/1 did not inhibit its conversion rate by the Kocuria palustris RS32 strain. The Acinetobacter sp. VT 11 strain utilized TNT as a sole substrate for growth; 3,5-dinitro-4-methyl anilide acetate and 2,6-dinitro-4-aminotoluene were identified as intermediates of TNT degradation by active strains of Pseudomonas sp. VT-7W and Kocuria rosea RS51. At the same time, 4-methyl-3,5-dinitroformamide was discovered for the first time upon the TNT destruction by the bacteria strains of Rhodococcus opacus 1G and Rhodococcus sp. VT-7. The active bacterial strains achieved an 82-90% destruction of TNT when they were introduced into the soil.     

溶微囊藻细菌的富集筛选及其菌群结构特征

利用铜绿微囊藻(Microcystis aeruginosa)作为溶藻对象富集、筛选, 获得一个稳定的溶藻菌群。采用叶绿素、PCR和变性梯度凝胶电泳(DGGE)方法研究溶藻过程及其细菌种群结构的变化。结果显示, 富集的溶藻菌经1×10-5稀释后仍有显著溶藻效果。Rubritepida菌C1、假单胞菌C2和鞘氨醇单胞菌C3是存在于铜绿微囊藻中的3种伴生细菌。加入富集的溶藻菌群后, 菌群结构发生明显的变化, Rubritepida菌C1、假单胞菌C2消失, 混合菌群包含未培养黄杆菌A2、鞘氨醇单胞菌C3和噬氢     

Time-dependent attachment mechanism of bacterial pathogen during ice-ice infection in Kappaphycus alvarezii (Gigartinales, Rhodophyta)

The mechanism of infection by Vibrio sp. P11 promoting the ice-ice disease in Kappaphycus alvarezii was investigated in vitro. Its intensity of infection differs from that of another ice-ice promoter (Cytophaga sp. P25) by promoting the disease much faster. However, when secondary infection by other bacteria starts, its ability to compete with these bacteria gradually diminishes, whereas, infection by P25, although not displaying such drastic effects as P11, shows consistent competitive ability against other bacteria. Time-series infection experiments with application of polyclonal antibodies to specifically detect Vibrio sp. P11 revealed that this bacterium has a high affinity for the seaweed especially when the latter is stressed. It promotes the disease after a rapid increase in cell density of up to 10⁷ g⁻¹ (wet wt.) in the first 24 h. This bacterial cell build-up may take only 1–2 h on stressed thalli, but takes about 24 h on non-stressed thalli. Build-up is not sustainable in non-stressed thalli as high density is usually followed by a sudden decline in cell number believed to result from an algal defence against potential pathogens. Inoculation of the bacterium on thalli incubated in continuous culture system extends the time of bacterial attachment due to laminar flow and, possibly, competition by existing bacteria on the seaweed surface and in ambient seawater medium. Motility-driven cell attachment by this bacterium is suggested as an important factor for infection. This revised version was published online in June 2006 with corrections to the Cover Date.     

Biotreatment of Industrial Wastewater by Selected Algal‐Bacterial Consortia

A new approach for remediation processes in highly polluted environments is presented. The efficiency of algal‐bacterial associations for the remediation of industrial wastewater of a pond in Samara, Russia, was investigated. After screening of algae and bacteria for the resistance to the wastewater the following strains were selected: the algal strains Chlorella sp. ES‐13, Chlorella sp. ES‐30, Scenedesmus obliquus ES‐55, several Stichococcus strains (ES‐19, ES‐85, ES‐86, ES‐87, ES‐88), and Phormidium sp. ES‐90 and the bacterial strains Rhodococcus sp. Ac‐1267, Kibdelosporangium aridum 754 as well as two unidentified bacterial strains (St‐1, St‐2) isolated from the collector pond. All the strains listed above were immobilized onto various solid carriers (capron fibers for algae; ceramics, capron and wood for bacteria) and used for biotreatment in a pilot installation. The results showed that the selected algae and bacteria formed stable consortia during the degradation of the waste, which was demonstrated for the first time for the green alga Stichococcus. Stichococcus and Phormidium cells attached to capron fibers with the help of slime and formed a matrix. This matrix fixed the bacteria and eukaryotic algae and prevented them from being washed off. A significant decrease in the content of the pollutants was observed: phenols were removed up to 85 %, anionic surface active substances (anionic SAS) up to 73 %, oil spills up to 96 %, copper up to 62 %, nickel up to 62 %, zinc up to 90 %, manganese up to 70 %, and iron up to 64 %. The reduction of the biological oxygen demand (BOD₂₅) and the chemical oxygen demand COD amounted to 97 % and 51 %, respectively.     

Co-Evolution of a Virus-Alga System

Plectonema boryanum, a filamentous blue-green alga, was cloned and then allowed to reach a steady state in a quasi-continuous culture in the presence of the algal virus, LPP-1. The culture was maintained for a 3.5-month period during which time at least four distinct culture lysings were evident. After the fourth lysis the culture reached a steady-state level which was identical in its algal concentration to the preinfection level. Upon testing the characteristics of the evolved alga and virus variants, the following was determined: cell variants resistant to both the original virus and the derived virus had evolved, and there was no evidence of lysogeny present among these cells. The evolved virus strains still grew on the parental algal strain, though with altered plaque morphology. Furthermore, they were antigenically similar to the parental virus, and showed no significant difference in adsorption rate or growth characteristics on parental cells. However, a low-grade chronic viral infection persisted in the culture. Rapid re-establishment of a dense, stable culture is apparently the normal laboratory response of a procaryotic cell-virus system.     

The enzymes of a marine bacterial isolate from the brown alga <Emphasis Type="Italic">Sargassum polycystum</Emphasis> agardh, 1821, that catalyzes the transformation of polyanionic oligo-and polysaccharides

A search for enzymes involved in the degradation of polyanionic polysaccharides (fucoidans and alginic acid) was conducted among bacterial epiphytes of the brown alga Sargassum polycystum that grows in the territorial waters of the Socialist Republic of Vietnam. Two resistant bacterial strains, F10 and F14, have been isolated from the algal microflora that degrade the thallus of the alga under laboratory conditions. These bacterial strains differed in the morphological, physiological, and biochemical characteristics and in the composition of enzymes. The strains were studied for the ability to synthesize intracellular oligo-and polysaccharide hydrolases and alginate lyases. The optimal conditions for the growth of bacterial strain F14 and the biosynthesis of fucoidanase and polymannuronate-specific alginate lyase were determined. The partially purified alginate lyase was stable at a temperature up to 40°C and had an optimal pH 6.0 and an optimal temperature 35°C.     

Nitrogen Effect on Water-Soluble Polysaccharide Accumulation in <Emphasis Type="Italic">Streblonema</Emphasis> sp. (Ectocarpales,Phaeophyceae)

The water-soluble polysaccharides of brown algae attract the increasing attention of researchers as an important class of polymeric materials of biotechnological interest. The sole source for production of these polysaccharides has been large brown seaweeds such as members of Laminariales and Fucales. A new source of water-soluble polysaccharides is suggested here: it is a filamentous brown alga Streblonema sp., which can be cultivated under controlled conditions in photobioreactors that allow obtaining algal biomass with reproducible content and quality of polysaccharides. The accumulation of water-soluble polysaccharides can be stimulated by macronutrient limitation. In response to nitrogen deficiency, Streblonema sp. accumulated water-soluble polysaccharides (WSPs) rich in laminaran. WSP accumulation started after 3–4 days following nitrate depletion and reached a plateau at around day 7. Polysaccharide accumulation was related to cellular nitrogen content. The critical internal N level that triggered the onset of polysaccharide accumulation was 2.3% dry weight (DW); at a cellular N concentration less than 1.4% DW, the polysaccharide synthesis stopped. Upon nitrate re-supply, mobilization of WSP occurred after 3 days. These results suggest that a two-stage cultivation process could be used to obtain large algal biomass with high water-soluble polysaccharide production: a first cultivation stage using nitrate-supplemented medium to accumulate algal biomass followed by a second cultivation stage in a nitrate-free medium for 3 to 7 days to enhance polysaccharide content in the alga.     

Bacillus cereus can attack the cell membranes of the alga Chara corallina by means of HlyII

We studied the influence of Bacillus cereus bacteria on cells of the freshwater alga Chara corallina. These bacteria and recombinant Bacillus subtilis strains are capable of producing the secreted toxin HlyII, which changes the electrophysiological parameters of the algal electrically excitable plasma membrane by forming pores. Cooperative incubation of bacterial cells, which carry active hlyII gene, and Chara corallina cells caused a decrease in the resting potential (V(m)) and plasma membrane resistance (R(m)) of algal cells. The efficiency of each strain was commensurable with its ability to produce HlyII. Purified hemolysin II caused a similar effect on V(m) and R(m) of intact and perfused cells. This protein changed the kinetics and magnitude of transient voltage-dependent calcium and calcium-activated chloride currents owing to the formation of additional Ca(2+)-permeable pores in algal cell membrane. Occurrence of the cellulose cell wall with pores 2.1 to 4.6nm in diameter suggests that HlyII molecules reach the plasma membrane surface strictly as monomers.     

Interactions between freshwater bacteria andAnkistrodesmus braunii in batch and continuous culture

Batch and continuous cultures ofAnkistrodesmus braunii were established in an inorganic medium with growth rate limited by P. In batch culture, inoculation of lake water bacterial isolates ofPseudomonas sp. andFlavobacterium sp. showed that thePseudomonas isolate was capable of more rapid growth on algal exudates of lytic products than was theFlavobacterium isolate. When inoculated singly into a continuous culture (D=0.267 day^–1; P level, 2M), theFlavobacterium isolate initially caused a decrease in the population density of the alga, but then steady states for both organisms were obtained. ThePseudomonas isolate under the same conditions caused a rapid washout of the algal culture, and steady-state conditions were never obtained. When thePseudomonas isolate was added to the two-member, steady-state system ofA. braunii andFlavobacterium, the algal population again washed out of the vessel, followed by theFlavobacterium and then thePseudomonas isolate. A transient increase in the P concentration to 200M in the culture vessel caused the low algal population level to increase, followed by increases in the bacterial isolates when the algal population was high enough to supply the required organic carbon source. The system demonstrated that competition for P between the alga and the bacteria can occur, and the results were dependent on the algal and bacterial relative growth rates. The bacterial growth rates were limited initially by organic substrates produced by the alga, and the different bacterial isolates competed for these substrates.     

Evaluation of candidate probiotic strains for gilthead sea bream larvae (Sparus aurata) using an in vivo approach

AIMS: The aim of this study was to evaluate the effect of six bacterial strains on gilthead sea bream larvae (Sparus aurata). METHODS AND RESULTS: Six bacterial strains isolated from well-performing live food cultures were identified by sequencing fragments of their 16s rDNA genome to the genus level as Cytophaga sp., Roseobacter sp., Ruergeria sp., Paracoccus sp., Aeromonas sp. and Shewanella sp. Survival rates of gilthead sea bream larvae transferred to seawater added these bacterial strains at concentrations of 6 +/- 0.3 x 10(5) bacteria ml(-1) were similar to those of larvae transferred to sterilized seawater and showed an average of 86% at 9 days after hatching, whereas, survival rates of larvae transferred to filtered seawater were lower (P < 0.05), and showed an average of 39%, 9 days after hatching. CONCLUSION: Several bacterial strains isolated from well-performing live food cultures showed a positive effect for sea bream larvae when compared with filtered seawater. SIGNIFICANCE AND IMPACT OF THE STUDY: The approach used in this study could be applied as an in vivo evaluation method of candidate probiotic strains used in the rearing of marine fish larvae.