Studies on pathogenic Vibrio parahaemolyticus during a warm weather season in the Seto Inland Sea,Japan

Vibrio parahaemolyticus is a potentially pathogenic bacterium, occurring naturally in estuarine and marine environments throughout the world. The incidence of this organism in an aquatic environment depends upon many ecofactors. Sea water and organic material were collected during the warm weather season from a coast of the Seto Inland Sea, Japan, and analysed to determine V. parahaemolyticus densities and the occurrence of pathogenic strains, defined as those possessing tdh and/or trh genes by polymerase chain reaction (PCR), using isolated DNA from enrichment culture of the samples. About 99% of samples were positive for V. parahaemolyticus with densities of 3 to >1400 cells per 100 ml of water or 10 g of organic samples by the most-probable-number (MPN)-PCR technique, but only 76.6% were positive by the conventional MPN culture technique, with densities ranging from 3 to >1400 cells per 100 ml of water or 10 g of organics. Furthermore, the tdh and trh genes were positive in 41.5% and 8.5% of samples, respectively, by the MPN-PCR technique. No tdh and trh gene-positive strains were isolated by the conventional MPN culture procedure. The difference in detection between the MPN culture and the MPN-PCR techniques appeared to be significant and may be attributed to different detection sensitivities and other factors.     

污水土地生态处理脱氮技术的中型试验研究

地沟式污水土地生态处理工艺,是自然生态净化与人工工艺相结合的小规模污水处理回用技术。它是采用土壤毛细管浸润扩散原理的浅型土壤处理技术,在人工可控条件下,将污水科学、合理地投配到设计定型的装置内,利用污水的能量,把其所携带的污染物,通过人工基质(土壤、砂、碎石等,填料-水-微生物-植物系统)的物质循环和能量流动,逐级降解;在不同的污染负荷、水力负荷下,完成一系列物理、化学、物理化学和微生物化学、生物化学的反应。通过以贵州典型的黄壤土为主配比的人工土作为处理系统填料的现场中型试验,探讨地沟式污水土地处理系统的脱氮效果及其影响因素。地沟式污水土地生态系统对氨氮和总氮去除效果良好,去除率分别达到84 .7%和70 .7% ,出水氨氮(14 .0 mg/L )和总氮(2 4 .7mg/L ) ,达到建设部颁发的生活杂用水水质标准。对处理系统微生物数量及分布的研究表明:处理系统中氮转化细菌丰富,氨化细菌为10 3～10 6 cfu MPN/g(土壤) (cfu:形成菌落数:MPN:最大可能数量) ,亚硝化菌为10 3～10 6 MPN/g(土壤) ,硝化菌10 4～10 6 MPN/g(土壤) ,反硝化细菌为10 3～10 6 MPN/g(土壤)。由硝化/反硝化实现生物脱氮是土地生态处理系统去除总氮的主要途径;建立土壤、土壤微生物、土壤植被环境以促进硝化作用是提高总     

Environmental investigation of potentially pathogenic Vibrio parahaemolyticus in the Seto-Inland Sea, Japan

Seawater and organic material (live and/or dead matter deposited on any substratum submersed in seawater) were collected during the cool weather season from a coast of the Seto-Inland Sea, Japan, and analyzed to determine Vibrio parahaemolyticus densities and the occurrence of pathogenic strains, defined as those possessing tdh and/or trh genes by the polymerase chain reaction (PCR), using isolated DNA from enrichment culture of the samples. About 95% of the samples were positive for V. parahaemolyticus (with densities of 3 to >1400 cells per 100 ml water or 10 g organic samples) by the most-probable-number (MPN)-PCR technique with species-specific toxR primers, but only 40% were positive by the conventional MPN-culture technique (with densities ranging from 3 to 240 cells per 100 ml water or 10 g organics). Furthermore, the tdh and trh genes were positive in 55% and 20% of samples, respectively, by the MPN-PCR technique. No tdh and trh gene-positive strains were isolated by the conventional MPN-culture procedure. The difference in detection between the MPN-culture and the MPN-PCR techniques appeared to be significant and may be attributed to different detection sensitivities and other factors.     

Luminescence-based nonextractive technique for in situ detection of Escherichia coli in soil

Measurement of light output by luminometry was used to estimate quantitatively the cell concentrations of luminescent strains of Escherichia coli in liquid culture and inoculated into soil. Strains were constructed in which luciferase production was autoinducible or constitutive. In the former, light output per cell varied considerably during growth but was constant in constitutive strains. In liquid culture, the lower detection limit was in the order of 10(2) cells ml-1. Sensitivity was reduced by approximately 1 order of magnitude for cells inoculated into soil, when 2 x 10(2) to 6 x 10(3) cells g of soil-1 could be detected. Light output measurements were obtained within 5 min of sampling, and luminometry therefore potentially offers a rapid and sensitive detection technique for genetically engineered microorganisms.     

Luminescence-based nonextractive technique for in situ detection of Escherichia coli in soil.

Measurement of light output by luminometry was used to estimate quantitatively the cell concentrations of luminescent strains of Escherichia coli in liquid culture and inoculated into soil. Strains were constructed in which luciferase production was autoinducible or constitutive. In the former, light output per cell varied considerably during growth but was constant in constitutive strains. In liquid culture, the lower detection limit was in the order of 10(2) cells ml-1. Sensitivity was reduced by approximately 1 order of magnitude for cells inoculated into soil, when 2 x 10(2) to 6 x 10(3) cells g of soil-1 could be detected. Light output measurements were obtained within 5 min of sampling, and luminometry therefore potentially offers a rapid and sensitive detection technique for genetically engineered microorganisms.     

Most probable number methodology for quantifying dilute concentrations and fluxes of Escherichia coli O157:H7 in surface waters

Aims:  To better understand the transport and enumeration of dilute densities of Escherichia coli O157:H7 in agricultural watersheds, we developed a culture-based, five tube-multiple dilution most probable number (MPN) method.
Methods and Results:  The MPN method combined a filtration technique for large volumes of surface water with standard selective media, biochemical and immunological tests, and a TaqMan confirmation step. This method determined E. coli O157:H7 concentrations as low as 0·1 MPN per litre, with a 95% confidence level of 0·01–0·7 MPN per litre. Escherichia coli O157:H7 densities ranged from not detectable to 9 MPN per litre for pond inflow, from not detectable to 0·9 MPN per litre for pond outflow and from not detectable to 8·3 MPN per litre for within pond. The MPN methodology was extended to mass flux determinations. Fluxes of E. coli O157:H7 ranged from <27 to >10⁴ MPN per hour.
Conclusion:  This culture-based method can detect small numbers of viable/culturable E. coli O157:H7 in surface waters of watersheds containing animal agriculture and wildlife.
Significance and Impact of the Study:  This MPN method will improve our understanding of the transport and fate of E. coli O157:H7 in agricultural watersheds, and can be the basis of collections of environmental E. coli O157:H7.     

土壤微生物PCR及分子杂交检测

ＰＣＲ技术在环境微生物的检测方面已得到越来越广泛的应用,Ｓｔｅｆａｎ等［１］利用ＰＣＲ技术检测土壤中的转基因细菌,后来用于检测土壤中不可培养的微生物［２］,跟踪环境中的特定细菌或ＤＮＡ［３］,揭示土壤生态系统的基因多样性［４］等。利用ＰＣＲ技术来检测…     

A method to evaluate survival of genetically engineered bacteria in soil extracts

A technique of potential use to the biotechnology industry was developed for studying the survival of bacteria in aqueous extracts of soil. The aqueous extracts of soil were placed into test tubes, amended as desired, inoculated with bacteria containing recombinant DNA, and incubated. Most bacteria introduced into filter-sterilized soil extracts were capable of multiplying and maintained populations of 10 E6 to 10 E8 cfu/ml over 13 days. However, bacteria introduced into nonsterile soil extracts at 10 E5 cfu/ml were found to decrease by 2–3 logs over a 13-day period. The soil extract method revealed that recombinant DNA plasmids had no significant effect on survival of thePseudomonas spp. andEscherichia coli strains examined. Extracts from soil provide a convenient and homogeneous milieu for estimating relative competitiveness and documenting survival characteristics of genetically engineered microorganisms. The use of aqueous extracts of soil offer convenience, a means of obtaining homogeneous cell suspensions, and ease of experimental replication over the inoculation of bacteria uniformly into soil.     

Recombinant and wild-type Pseudomonas aureofaciens strains introduced into soil microcosms: effect on decomposition of cellulose and straw

The effect of a genetically engineered Pseudomonas aureofaciens (Ps3732RNL11) strain (GEM) and the parental wild-type (Ps3732RN) on decomposition of cellulose paper, straw and calico cloth was assessed after 18 weeks incubation in laboratory soil microcosms. Effect(s) of inoculum density (10³, 10⁵, and 10⁸ cells/ g dry soil) and single versus multiple bacterial inoculations were also investigated. Cellulose paper was completely decomposed after 18 weeks in all treatments. There were no significant differences (95% level), between treatments, in percentage decomposition of either straw or calico cloth. Recovery of the GEM at 18 weeks, using viable plating, was limited to treatments originally receiving 10⁸ cells/g dry soil. Log 1.8 CFU/g dry soil were recovered from the single dose treatment while log 4.2 CFU/g dry soil were recovered from the multiple dose treatment Biolog metabolic tests were used to determine if the GEM or parental wild-type had any effect on overall carbon utilization in soil. Results suggested they did not. Detection of the recombinant lacZY gene sequence in soil using PCR suggested the possibility of viable but nonculturable cells and/or persistence of chromosomal DNA.     

Most-probable-number technique for the enumeration of aromatic degraders in natural environments

A most-probable-number (MPN) method is described for the enumeration of heterotrophic populations capable of utilizing chlorinated and nonchlorinated benzoates and phenols as sole carbon sources. A correlation coefficient of 0.91 was obtained between the numbers determined by the MPN technique and the standard plate count. The MPN method gave realistic cell counts when population densities were low, and the presence of oligocarbophiles did not give spurious results.     

Survival of genetically modified Pseudomonas fluorescens introduced into subtropical soil microcosms

Abstract A genetically modified strain of Pseudomonas fluorescens and its parent showed grossly similar decline rates following introduction into subtropical clay and sandy soils. In unplanted clay soit at pH 6.9 and 25°C, population densities declined progressively from about 10⁸ to 10³ colony forming units (cfu) g⁻¹ dry soil over 75 days, but in unplanted sandy soil the introduced populations could not be detected after 25 days. In clay soil at pH 8.7 or 4.7, or at environmental temperature, decay rates were enhanced as compared to those at pH 6.9 and 25°C. Counts of introduced strains in clay bulk soil and in rhizosphere and rhizoplane of maize suggested that the introduced bacteria competed well with the native bacteria, and colonized the roots at about 10⁶ cfu g⁻¹ dry root at 25°C, over 20 days. However, rhizoplane colonization was lower at environmental temperature. The decay rate of both strains was slower in planted than in unplanted sandy soil. The population densities in the rhizosphere and rhizoplane in the sandy soil were significantly lower than those in the clay soil. Both introduced strains colonized the maize roots in both soils, using seeds coated with bacteria in 1% carboxymethyl cellulose. Introduced cells were localized at different sites along the roots of plants developing in clay soil, with higher densities in the original (near the seeds) and root hair zones as compared to the intermediate zones. No significant difference was observed between the extent of root colonization of the genetically modified strain and its parent.     

Genetically Engineered Erwinia carotovora in Aquatic Microcosms: Survival and Effects on Functional Groups of Indigenous Bacteria

The survival of genetically engineered Erwinia carotovora L-864, with a kanamycin resistance gene inserted in its chromosome, was monitored in the water and sediment of aquatic microcosms. The density of genetically engineered and wild-type E. carotovora strains declined at the same rate, falling in 32 days below the level of detection by viable counts. We examined the impact of the addition of genetically engineered and wild-type strains on indigenous bacteria belonging to specific functional groups important in nutrient cycling. For up to 16 days, the densities of total and proteolytic bacteria were significantly higher (P < 0.05) in microcosms inoculated with genetically engineered or wild-type E. carotovora, but by 32 days after inoculation, they had decreased to densities similar to those in control microcosms. Inoculation of genetically engineered or wild-type E. carotovora had no apparent effect on the density of amylolytic and pectolytic bacteria in water and sediment. Genetically engineered and wild-type E. carotovora did not have significantly different effects on the densities of specific functional groups of indigenous bacteria (P > 0.05).     

Survival of soft rot coliforms, Erwinia carotovora subsp. carotovora and E. carotovora subsp. atroseptica in soil in Scotland

An enrichment method was used to monitor Erwinia carotovora in soil or the rhizosphere of different crops and weeds in 17 fields with different cropping histories on three farms. The bacteria were detected in all fields not cropped with potatoes, although not consistently, and the mean annual frequency of detection was generally low (< 10%). Fields in which potatoes were grown were extensively contaminated after harvest in September but contamination declined over the winter to very low levels by early summer in the following year. Contamination level tended to rise in some fields without potatoes regardless of their cropping history but for only a short time during autumn and winter. The bacteria were no more frequent in rhizosphere soil of any of the weeds or crops examined, with the exception of brassicas, than in bare soil. In fields where more than 16 months had elapsed since cropping with potatoes, 91% of erwinia isolates obtained were E. carotovora subsp. carotovora , the remainder being E. carotovora subsp. atroseptica. The bacteria were shortlived in soil and in the rhizospheres of inoculated field and pot grown crop and weed plants. Longevity was greater in dry (10% moisture) than in wet (21% moisture) soil and decreased as temperatures rose, particularly above 25°C. Survival was best in association with brassica plants, moderate on grasses and cereals, and least on potatoes and weeds. E.c. carotovora survived better than E.c. atroseptica. Because survival of the bacteria in soil is apparently restricted, their presence in fields could be attributed to recurrent introductions from different sources.     

Prey range characterization, ribotyping, and diversity of soil and rhizosphere Bdellovibrio spp. isolated on phytopathogenic bacteria

Thirty new Bdellovibrio strains were isolated from an agricultural soil and from the rhizosphere of plants grown in that soil. Using a combined molecular and culture-based approach, we found that the soil bdellovibrios included subpopulations of organisms that differed from rhizosphere bdellovibrios. Thirteen soil and seven common bean rhizosphere Bdellovibrio strains were isolated when Pseudomonas corrugata was used as prey; seven and two soil strains were isolated when Erwinia carotovora subsp. carotovora and Agrobacterium tumefaciens, respectively, were used as prey; and one tomato rhizosphere strain was isolated when A. tumefaciens was used as prey. In soil and in the rhizosphere, depending on the prey cells used, the concentrations of bdellovibrios were between 3 x 10(2) to 6 x 10(3) and 2.8 x 10(2) to 2.3 x 10(4) PFU g(-1). A prey range analysis of five soil and rhizosphere Bdellovibrio isolates performed with 22 substrate species, most of which were plant-pathogenic and plant growth-enhancing bacteria, revealed unique utilization patterns and differences between closely related prey cells. An approximately 830-bp fragment of the 16S rRNA genes of all of the Bdellovibrio strains used was obtained by PCR amplification by using a Bdellovibrio-specific primer combination. Soil and common bean rhizosphere strains produced two and one restriction patterns for this PCR product, respectively. The 16S rRNA genes of three soil isolates and three root-associated isolates were sequenced. One soil isolate belonged to the Bdellovibrio stolpii-Bdellovibrio starrii clade, while all of the other isolates clustered with Bdellovibrio bacteriovorus and formed two distantly related, heterogeneous groups.     

Survival of the phytopathogen Erwinia carotovora subsp. carotovora in sterile and non-sterile soil, sand and their admixture

Survival of phytopathogens in irrigation water and irrigated soil is of major concern to the agricultural community. In the present study, an Erwinia carotovora subsp. carotovora strain was tested for survival capability in three non-sterile and heat-sterilized soil matrices (soil, sand and soil + sand) over 35 d. In all non-sterile soil matrices, Erw. carotovora subsp. carotovora numbers declined below the detection limit over 35 d, the main variance being the decline rate related to nutrients available in the different matrices (soil, soil + sand and sand respectively). In heat-sterilized soil and soil + sand matrices Erw. carotovora subsp. carotovora revealed a regrowth, while in sterile sand matrix its decline was lower over the same time period. In previous published reports, when soil was sterilized by irradiation, such a regrowth was not observed. Application of an initial single load of sodium nitrate solution (70 mg l⁻¹) was found to extend bacteria survival rate in non-sterile and sterile soil columns. In sterile soil columns supplemented with sodium nitrate, Erw. carotovora subsp. carotovora did survive well for up to 60 d, with a major regrowth over the first 12 d and decline up to day 60, reaching initial loading numbers. The information on the potential survival of Erw. carotovora subsp. carotovora in soil for up to 35 d and regrowth in sterile soil should be of concern, especially when irrigation is performed with poor quality water.     

Detection and counting of Nitrobacter populations in soil by PCR.

Although the biological conversion of nitrite to nitrate is a well-known process, studies of Nitrobacter populations are hindered by their physiological characteristics. This report describes a new method for detecting and counting Nitrobacter populations in situ with the PCR. Two primers from the 16S rRNA gene were used to generate a 397-bp fragment by amplification of Nitrobacter species DNA. No signal was detected from their phylogenetic neighbors or the common soil bacteria tested. Extraction and purification steps were optimized for minimal loss and maximal purity of soil DNA. The detection threshold and accuracy of the molecular method were determined from soil inoculated with 10, 10(2), or 10(3) Nitrobacter hamburgensis cells per g of soil. Counts were also done by the most-probable-number (MPN)-Griess and fluorescent antibody methods. PCR had a lower detection threshold (10(2) Nitrobacter cells per g of soil) than did the MPN-Griess or fluorescent antibody method. When PCR amplification was coupled with the MPN method, the counting rate reached 65 to 72% of inoculated Nitrobacter cells. Tested on nonsterile soil, this rapid procedure was proved efficient.     

Density independent population dynamics by Trichoderma virens in soil and defined substrates

Classical models of population dynamics predict that with increasing initial population densities the per capita growth will diminish. Observations over a broad range of initial densities with a wild-type and a genetically engineered strain of the filamentous fungus, Trichoderma virens (Arx), in soil and autoclaved soil differed from these predictions. The per capita growth response of T. virens in vitro was found to be density dependent on potato dextrose agar, but density independent on water agar. Further experiments with a defined, carbon-free medium (Vogel's medium) and, with the same medium containing sucrose, indicated that density dependent per capita growth occurred in the nutrient-rich medium but not the oligotrophic medium. This hypothesis was tested and supported experimentally through observation of density dependent per capita growth after adding nutrients to autoclaved soil. Development of better models of population dynamics will be important to predict successfully the likelihood and extent of establishment after field release of microorganims.     

Monitoring survival and gene transfer in soil microcosms of recombinant Escherichia coli designed to represent an industrial production strain

Summary A genetically engineered microorganism (GEM) was designed to exemplify bacterial strains used for the production of biological material in industry. The recombinant DNA was located on a safety plasmid (pUC19). Survival and persistence of the GEM and its recombinant DNA (rDNA) was determined in soil microcosms by using different monitoring methods, including the polymerase-chain reaction, to amplify and detect the specific rDNA. Depending on nutritional status, both the GEM and its rDNA had disappeared within 16 (amended soil) or 28 days (non-amended soil) with a limit of detection of 5 cells/g soil and 20 fg DNA/g soil.Offprint requests to: F.Schmidt     

Genetically Engineered Erwinia carotovora: Survival, Intraspecific Competition, and Effects upon Selected Bacterial Genera

Environmental use of genetically engineered microorganisms has raised concerns about potential ecological impact. This research evaluated the survival, competitiveness, and effects upon selected bacterial genera of wild-type and genetically engineered Erwinia carotovora subsp. carotovora to ascertain if differences between the wild-type and genetically engineered strains exist in soil microcosms. The engineered strain contained a chromosomally inserted gene for kanamycin resistance. No significant differences in survival in nonsterile soil over 2 months or in the competitiveness of either strain were observed when the strains were added concurrently to microcosms. For reasons that remain unclear, the engineered strain did survive longer in sterilized soil. The effects of both strains on total bacteria, Pseudomonas and Staphylococcus strains, and actinomycetes were observed. While some apparent differences were observed, they were not statistically significant. A better understanding of the microbial ecology of engineered bacteria, especially pathogens genetically altered for use as biological control agents, is essential before commercial applications can be accomplished.     

Persistence of Perchlorate and the Relative Numbers of Perchlorate- and Chlorate-Respiring Microorganisms in Natural Waters, Soils, and Wastewater

Cell numbers of perchlorate (PRM)- and chlorate (CRM)-reducing microorganisms and the persistence of perchlorate were determined in samples of soils, natural waters, and wastewater incubated under laboratory conditions. Complete perchlorate reduction in raw wastewater and creek water was achieved in 4 to 7 days and 8 to 29 days, respectively, depending on the individual growth substrate (acetate, lactate, citric acid, or molasses) employed. Perchlorate persisted in most mixed cultures developed with 2 g of “pristine” soil, but declined in mixed cultures developed with 100 g of soil. Less than seven days were required to completely reduce perchlorate in cultures started with 10 g of a perchlorate-contaminated soil obtained from a site in Texas. The concentration of PRM was estimated using a 5-tube most probable number (MPN) procedure. To account for discrepancies due to differences in the total number of bacteria (per mass of sample) in the samples, difficulty in removing bacteria from soil samples, and the lack of an unequivocal method to measure total viable cells in these different systems, we normalized our MPN results on the basis of 10⁶ or 10⁹ total bacteria counted using acridine orange direct counts (AODC). There were more PRM in wastewater samples on a per-cell basis (15 to 350 PRM/10⁶-AODC) than in water samples (0.02 to 0.4 PRM/10⁶-AODC). There were also more PRM in soils from sites exhibiting direct evidence of perchlorate contamination (100 to 200 PRM/10⁹-AODC) than from other sites (nondetectable to 0.77 PRM/10⁹-AODC). These results demonstrate that perchlorate-reducing bacteria are present at perchlorate-contaminated sites, and that perchlorate can be degraded by these microorganisms through the addition of different electron donors, such as acetate and lactate.