Pathogenicity of Vibrio alginolyticus for Cultured Gilt-Head Sea Bream (Sparus aurata L.)

The in vivo and in vitro pathogenic activities of whole cells and extracellular products of Vibrio alginolyticus for cultured gilt-head sea bream were evaluated. The 50% lethal doses ranged from 5.4 × 10⁴ to 1.0 × 10⁶ CFU/g of body weight. The strains examined had the ability to adhere to skin, gill, and intestinal mucus of sea bream and to cultured cells of a chinook salmon embryo cell line. In addition, the in vitro ability of V. alginolyticus to adhere to mucus and skin cells of sea bream was demonstrated by scanning electron microscopy. The biological activities of extracellular products of V. alginolyticus were hydrolytic activities; the products were able to degrade sea bream mucus. V. alginolyticus was cytotoxic for fish cell lines and lethal for sea bream. Moreover, the extracellular products could degrade sea bream tissues. However, experiments performed with the bath immersion inoculation technique demonstrated that V. alginolyticus should be considered a pathogen for sea bream only when the mucus layer is removed and the skin is damaged.     

Chemotaxis of Pathogenic Vibrio Strains towards Mucus Surfaces of Gilt-Head Sea Bream (Sparus aurata L.)

Vibrio anguillarum and Vibrio alginolyticus exhibited significant adhesion to and chemotactic abilities towards mucus collected from the skin, gills, and intestine of gilt-head sea bream. Quadratic polynomial models for chemotaxis designed to estimate the influence of temperature demonstrated a differential bacterial chemotaxis depending of the source of the mucus, with the chemotaxis towards intestinal mucus being the least influenced.     

Characterization of Pseudomonas spp. associated with spoilage of gilt-head sea bream stored under various conditions.

The population dynamics of pseudomonads in gilt-head sea bream Mediterranean fish (Sparus aurata) stored under different conditions were studied. Phenotypic analysis and sodium dodecyl sulfate-polyacrylamide gel electrophoresis of whole-cell proteins were performed to identify a total of 106 Pseudomonas strains isolated from S. aurata stored under different temperatures (at 0, 10, and 20 degrees C) and packaging conditions (air and a modified atmosphere of 40% CO(2)-30% N(2)-30% O(2)). Pseudomonas lundensis was the predominant species, followed by Pseudomonas fluorescens, while Pseudomonas fragi and Pseudomonas putida were detected less frequently. Fluorescent Pseudomonas strains dominated under air conditions, while proteolytic and less lipolytic strains dominated under modified-atmosphere packaging. Different storage conditions appear to govern the selection of pseudomonads in gilt-head sea bream fish.     

Survival of Campylobacter jejuni under Conditions of Atmospheric Oxygen Tension with the Support of Pseudomonas spp.

Campylobacter jejuni is a major food-borne pathogen. Despite causing enteritis in humans, it is a well-adapted intestinal microorganism in animals, hardly ever generating disease symptoms. Nevertheless, as a true microaerophilic microorganism it is still puzzling how Campylobacter cells can survive on chicken meat, the main source of human infection. In this study, we demonstrate that C. jejuni is able to withstand conditions of atmospheric oxygen tension when cocultured with Pseudomonas species, major food-spoiling bacteria that are frequently found on chicken meat in rather high numbers. Using an in vitro survival assay, interactions of 145 C. jejuni wild-type strains and field isolates from chicken meat, broiler feces, and human clinical samples with type strains and food isolates of Pseudomonas spp., Proteus mirabilis, Citrobacter freundii, Micrococcus luteus, and Enterococcus faecalis were studied. When inoculated alone or in coculture with Proteus mirabilis, Citrobacter freundii, Micrococcus luteus, or Enterococcus faecalis type strains, Campylobacter cells were able to survive ambient oxygen levels for no more than 18 h. In contrast, Campylobacter bacteria inoculated with type strains or wild-type isolates of Pseudomonas showed a prolonged aerobic survival of up to >48 h. This microbial commensalism was diverse in C. jejuni isolates from different sources; isolates from chicken meat and humans in coculture with Pseudomonas putida were able to use this survival support better than fecal isolates from broilers. Scanning electron microscopy revealed the development of fiberlike structures braiding P. putida and C. jejuni cells. Hence, it seems that microaerophilic C. jejuni is able to survive ambient atmospheric oxygen tension by metabolic commensalism with Pseudomonas spp. This bacterium-bacterium interaction might set the basis for survival of C. jejuni on chicken meat and thus be the prerequisite step in the pathway toward human infection.Campylobacter food-borne infections are the most prevalent bacterial enteric infections in humans in industrialized and developing countries (1). It has been shown that most human infections are related to poultry meat and food produced from cattle or sheep (34, 41). Campylobacter jejuni, the species most frequently causing human disease, can be isolated from the animal intestinal tract at levels of up to 10⁹ CFU per gram of feces and can thus be called a well-adapted intestinal microorganism (30, 37). Nevertheless, because it causes human disease as a food-borne pathogen, it has to survive outside the gut. By cross-contamination at the level of the abattoir, Campylobacter bacteria hit the meat surface and have to adapt to different environmental challenges. C. jejuni is a true microaerophilic bacterium; thus, on the one hand it requires oxygen, but on the other hand it cannot grow under normal atmospheric oxygen tension conditions (15). Despite its sensitivity to high oxygen tension in vitro, viable and culturable Campylobacter bacteria can be isolated from nonskinned chicken meat at frequencies of 10⁴ CFU/g (9, 19). Assumptions on the mechanisms by which Campylobacter cells survive on meat surfaces are diverse, for example, by growing in biofilms, entering a “viable but nonculturable state,” or interacting with other microorganisms.For instance, C. jejuni is able to resist protozoa digestion and can parasitize inside protozoa, e.g., Tetrahymena pyriformis (35). This mechanism provides survival in harsh environments and resistance to antimicrobial substances and thus enhances the potential for transmission. But bacterium-bacterium interaction has also been demonstrated to be of a high level of importance for intestinal survival and uptake (20). Accordingly, members of Campylobacter have been identified to initiate cellular uptake of commensal bacteria into enterocytes (14). However, a bacterial community can also mean competition, e.g., bacteriocin production by Lactobacillus salivarius that is effective against Campylobacter colonization (36).Meat surfaces harbor numerous bacterial species (24). Some of these bacteria have adapted to this specific environmental niche and are well-known spoilage bacteria. Most relevant species belong to the family Pseudomonadaceae. But also different members of the Enterobacteriaceae can be found on meat. To date, information regarding the interaction between spoilage bacteria and pathogens is of increasing importance for public health safety measures.Hence, experimental data on the survival of C. jejuni isolates in the presence of selected meat-spoiling bacteria were analyzed and clearly demonstrated a specific interaction with type strains and isolates of Pseudomonas putida, Pseudomonas fragi, and Pseudomonas fluorescens from chicken meat surfaces.     

Biological Control of Fire Blight of Hawthorn (Crataegus monogyna) with Fluorescent Pseudomonas spp. under Protected Conditions

Naturally-occurring epiphytic fluorescent pseudomonads were isolated and characterized in terms of their potential to control fire blight infection of hawthorn, caused by Erwinia amylovora. Preliminary testing and selection of antagonists using an immature pear fruit assay gave some inconsistency in the amount of pathogen suppression on the pear tissue and also in the prediction of biocontrol effectiveness on the intact plant. Selected antagonists provided significant but variable control of fire blight under protected (polythene tunnel and glasshouse) conditions, with isolates HL83 and HL99 giving control of both blossom-blight and shoot-blight. In some cases the degree of control was equal to that of chemical treatments, including agrimycin 17 and experimental bactericides, and was achieved without any numerical advantage of applied control agent over pathogen. The timing of pseudomonad application in relation to pathogen inoculation was found to have a significant effect on the level of control of blossom-blight.     

Isolation and Characterization of Agar-degrading Paenibacillus spp. Associated with the Rhizosphere of Spinach

Agar-degrading bacteria in spinach plant roots cultivated in five soils were screened, and four strains of Paenibacillus sp. were isolated from roots cultivated in three soils. The agar-degrading bacteria accounted for 1.3% to 2.5% of the total bacteria on the roots. In contrast, no agar-degrading colony was detected in any soil (non-rhizosphere soil samples) by the plate dilution method, and thus these agar-degrading bacteria may specifically inhabit plant roots. All isolates produced extracellular agarase, and could grow using agar in the culture medium as the sole carbon source. Zymogram analyses of agarase showed that all four isolates extracellularly secreted multiple agarases (75-160 kDa). In addition, the isolates degraded not only agar but also various plant polysaccharides, i.e., cellulose, pectin, starch, and xylan.     

Genetic Diversity and Spoilage Potentials among Pseudomonas spp. Isolated from Fluid Milk Products and Dairy Processing Plants

Degradation of milk components through various enzymatic activities associated with the contamination of dairy products by Pseudomonas spp. can reduce the shelf life of processed milk. Reliable methods for differentiating among Pseudomonas spp. strains are necessary to identify and eliminate specific sources of bacterial contamination from dairy processing systems. To that end, we assessed the genetic diversity and dairy product spoilage potentials among a total of 338 Pseudomonas spp. isolates from raw and pasteurized milk and from environmental samples collected from four dairy processing plants. The majority of isolates were identified as P. fluorescens and P. putida by API 20 NE. A total of 42 different ribotype patterns were identified among a subset of 81 isolates. The presence of many different ribotypes within this collection indicates high genetic diversity among the isolates and suggests multiple origins of contamination within the processing plant and in dairy products. The extracellular enzyme activity patterns among Pseudomonas isolates appeared to be associated with ribotypes. Isolates with the same ribotype frequently had the same extracellular protease, lecithinase, and lipase activities. For example, isolates grouped in ribotype 55-S-6 had the highest extracellular protease activity, while those in ribotypes 50-S-8 and 72-S-3 had the highest extracellular lipase activities. We conclude that ribotyping provides a reliable method for differentiating Pseudomonas strains with dairy food spoilage potential.     

Soil Properties,Nutrient Dynamics,and Soil Enzyme Activities Associated with Garlic Stalk Decomposition under Various Conditions

The garlic stalk is a byproduct of garlic production and normally abandoned or burned, both of which cause environmental pollution. It is therefore appropriate to determine the conditions of efficient decomposition, and equally appropriate to determine the impact of this decomposition on soil properties. In this study, the soil properties, enzyme activities and nutrient dynamics associated with the decomposition of garlic stalk at different temperatures, concentrations and durations were investigated. Stalk decomposition significantly increased the values of soil pH and electrical conductivity. In addition, total nitrogen and organic carbon concentration were significantly increased by decomposing stalks at 40°C, with a 5∶100 ratio and for 10 or 60 days. The highest activities of sucrase, urease and alkaline phosphatase in soil were detected when stalk decomposition was performed at the lowest temperature (10°C), highest concentration (5∶100), and shortest duration (10 or 20 days). The evidence presented here suggests that garlic stalk decomposition improves the quality of soil by altering the value of soil pH and electrical conductivity and by changing nutrient dynamics and soil enzyme activity, compared to the soil decomposition without garlic stalks.     

Lactobacillus oligofermentans sp. nov., Associated with Spoilage of Modified-Atmosphere-Packaged Poultry Products

Unidentified lactic acid bacterium (LAB) isolates which had mainly been detected in spoiled, marinated, modified atmosphere packaged (MAP) broiler meat products during two previous studies, were identified and analyzed for their phenotypic properties and the capability to produce biogenic amines. To establish the taxonomic position of these isolates, 16S rRNA gene sequence analysis, numerical analysis of ribopatterns, and DNA-DNA hybridization experiments were done. Unexpectedly for a meat-spoilage-associated LAB, the strains utilized glucose very weakly. According to the API 50 CHL test, arabinose and xylose were the only carbohydrates strongly fermented. None of the six strains tested for production of histamine, tyramine, tryptamine, phenylethylamine, putrescine, and cadaverine were able to produce these main meat-associated biogenic amines in vitro. The polyphasic taxonomy approach showed that these strains represent a new Lactobacillus species. The six isolates sequenced for the 16S rRNA encoding genes shared the highest similarity (95.0 to 96.3%) with the sequence of the Lactobacillus durianis type strain. In the phylogenetic tree, these isolates formed a distinct cluster within the Lactobacillus reuteri group, which also includes L. durianis. Numerical analyses of HindIII-EcoRI ribotypes placed all isolates together in a cluster with seven subclusters well separated from the L. reuteri group reference strains. The DNA-DNA hybridization levels between Lactobacillus sp. nov. isolates varied from 67 to 96%, and low hybridization levels (3 to 15%) were obtained with the L. durianis type strain confirming that these isolates belong to the same species different from L. durianis. The name Lactobacillus oligofermentans sp. nov. is proposed, with strain LMG 22743^T (also known as DSM 15707^T or AMKR18^T) as the type strain.     

Delignification of Wheat Straw by Pleurotus spp. under Mushroom-Growing Conditions

Pleurotus sajor-caju, P. sapidus, P. cornucopiae, and P. ostreatus mushrooms were produced on unsupplemented wheat straw. The yield of mushrooms averaged 3.6% (dry-weight basis), with an average 18% straw weight loss. Lignin losses (average, 11%) were lower than cellulose (20%) and hemicellulose (50%) losses. The cellulase digestibility of the residual straw after mushroom harvest was generally lower than that of the original straw. It does not appear feasible to simultaneously produce Pleurotus mushrooms and a highly delignified residue from wheat straw.     

Cellulolytic Bacteria Associated with Sloughing Spoilage of California Ripe Olives

Sloughing spoilage of California ripe olives during processing is characterized by severe softening, skin rupture, and flesh sloughing. It was assumed that cellulolytic activity was responsible for skin rupture and sloughing of flesh, and so a deliberate search was made for cellulolytic bacteria from olives undergoing sloughing spoilage. A bacterium identified as Cellulomonas flavigena was highly cellulolytic, attacking filter paper, carboxymethyl cellulose (CMC) gel, and olive tissue. Other bacteria attacking CMC, but not filter paper, enhanced the activity of the Cellulomonas strain when grown in mixed culture, although they did not, in pure culture, have any effect on filter paper. These latter cultures (all degraded olive tissue) represented the genera Xanthomonas, Aerobacter, and Escherichia. Other noncellulolytic bacteria belonging to the genera Alcaligenes, Kurthia, and Micrococcus also were used for study of mixed culture fermentation of cellulose by C. flavigena. Cellobiose accumulation at levels of 1.0% (w/v) and above suppressed growth of C. flavigena.     

Biological suppression of rice diseases by Pseudomonas spp. under saline soil conditions

The aim of this study was to develop antagonistic strains specific for the coastal agricultural niche in Southern India. Indigenous Pseudomonas strains isolated from rhizosphere of rice cultivated in the coastal agri-ecosystem were screened for in vitro antibiosis against Xanthomonas oryzae pv. oryzaeand Rhizoctonia solani– the bacterial leaf blight (BB) and sheath blight (ShB) pathogens of rice (Oryza sativa) respectively. The strains exhibiting antibiosis were tested in the greenhouse under normal and saline soil conditions. The antagonists suppressed BB by 15 to 74% in an unamended soil. The efficient strains were tested under saline soil conditions and found to suppress disease by 46 to 82%. Similarly, incidence of ShB was also suppressed by 30 to 57% in the unamended soil by the efficient strains which, under saline soil conditions, were found to suppress ShB by 19 to 51%. Four strains of Pseudomonas tested suppressed both BB and ShB diseases in rice, of which three were efficient under both natural and saline soil conditions.     

Identification and Characterization of Leuconostoc carnosum, Associated with Production and Spoilage of Vacuum-Packaged, Sliced, Cooked Ham

Leuconostoc carnosum was shown to be the specific spoilage organism in vacuum-packaged, sliced, cooked ham showing spoilage during 3 weeks of shelf life. Identification of the specific spoilage organism was done by use of phenotypic data and ClaI, EcoRI, and HindIII reference strain ribopatterns. One hundred L. carnosum isolates associated with the production and spoilage of the ham were further characterized by pulsed-field gel electrophoresis (PFGE), together with some meat-associated Leuconostoc species: L. citreum, L. gelidum, L. mesenteroides subsp. dextranicum, and L. mesenteroides subsp. mesenteroides. ApaI and SmaI digests divided the industrial L. carnosum strains into 25 different PFGE types, ApaI and SmaI types being consistent. Only one specific PFGE type was associated with the spoiled packages. This type also was detected in air and raw-meat mass samples. The spoilage strain did not produce bacteriocins. Only seven isolates belonging to three different PFGE types produced bacteriocins. Similarity analysis of the industrial L. carnosum strains revealed a homogeneous cluster which could be divided into eight subclusters consisting of strains having at most three-fragment differences. The L. carnosum cluster was clearly distinguished from the other meat-associated leuconostoc clusters, with the exception of the L. carnosum type strain. Ribotyping can be very helpful in the identification of L. carnosum, but its discriminatory power is too weak for strain characterization. PFGE provides good discrimination for studies dealing with the properties of homogeneous L. carnosum strains.     

Rhizoctonia spp. Associated with Container-Grown Ericaceous Plants in Scotland

Fungi with Rhizoctonia-like mycelia were isolated from the foliage, stem-base and roots of ericaceous plants collected from nurseries in Scotland. Isolated fungi were identified as either binucleate Rhizoctonia spp. or Rhizoctonia solani on the basis of hyphal characteristics and nuclear number. The optimum temperature range for growth of binucleate Rhizoctonia spp. and R. solani was 20 and 25 C, resepctively. All isolates tested for pathogenicity caused foliar browning, and webs of mycelial growth were observed on dead and dying foliage. Binucleate Rhizoctonia spp. and R. solani are recorded for the first time on container-grown ericaceous plants in Scotland.     

Removal of copper ion by Pseudomonas spp.

Copper-resistant Pseudomonas sp. 41Y, Pseudomonas pseudomallei 13-1 and Pseudomonas aeruginosa 7 were used in the present study. When the latter two organisms were added to copper-containing 1/3 strength Tryptic Soy Broth, more than 99.5% of the copper ion was removed from the medium within 24 h. If copper solution was added to hog waste slurry, a reduction in the copper ion concentration could be detected only when the added bacteria started to grow in it, whereas in a mineral medium supplemented with glycerol-2-phosphate, both bacteria could remove about 50% of the copper ion from the medium within 24 h. When cell suspension of Pseudomonas sp. 41Y was autoclaved, no copper ion removal was observed. Different incubation temperatures, including 30 degrees C, 37 degrees C and 45 degrees C, had no effect on the percent of copper ion removed by both Pseudomonas sp. 41Y and P. pseudomallei 13-1. On the other hand, if the pH value of the solution was lowered from 8.2 to 6.0, there was a drastic decrease in copper removal. A similar reduction of copper ion removal ability was also observed with the addition of lead ion. When cells of Pseudomonas sp. 41Y were embedded in sodium alginate, there was a decrease in its ability to remove copper ion as compared to the free-living cells.     

Turnover of Phospholipids in Bacillus cereus under Various Growth Conditions

As a search for natural antioxidants from plant materials, strong antioxidative activity was observed in leaf waxes extracted from Eucalyptus species. A novel type of antioxidant was isolated from the leaf wax of Eucalyptus globulus and identified as n-tritriacontan-16,18-dione. Antioxidative activities were determined by different methods; a thiocyanate method, a thiobarbituric acid method, a total carbonyl value method and a weighing test. The anti-oxidant showed remarkable antioxidative activity in a water/alcohol system and was more effective than α-tocopherol and BHA; however, it has no antioxidative activity in an oil system.