Effects of nutrient deprivation on Vibrio cholerae

Environmental and clinical strains of Vibrio cholerae were exposed to nutrient-free artificial seawater and filtered natural seawater microcosms for selected time intervals and examined for changes in cell morphology and number. Cells observed by transmission electron and epifluorescence microscopy were found to undergo gross alterations in cell morphology with time of exposure. The vibroid cells decreased in volume by 85% and developed into small coccoid forms surrounded by remnant cell walls. The initial number of cells inoculated into nutrient-free microcosms (culturable count and direct viable count) increased 2.5 log10 within 3 days, and even after 75 days the number of viable cells was still 1 to 2 log10 higher than the initial inoculum size. Nutrient-depleted coccoid-shaped cells were restored to normal size and assumed a bacillary shape within 3 h and began to divide within 5 h after nutrient supplementation. The increase in cell number and decrease in cell volume under nutrient-depleted conditions, as well as the rapid growth response after nutrient supplementation, may describe some of the survival mechanisms of V. cholerae in the aquatic environment.     

Resuscitation of Vibrio vulnificus from the viable but nonculturable state.

Stationary-phase-grown cells of the estuarine bacterium Vibrio vulnificus became nonculturable in nutrient-limited artificial seawater microcosms after 27 days at 5 degrees C. When the nonculturable cells were subjected to temperature upshift by being placed at room temperature, the original bacterial numbers were detectable by plate counts after 3 days, with a corresponding increase in the direct viable counts from 3% to over 80% of the total cell count. No increase in the total cell count was observed during resuscitation, indicating that the plate count increases were not due to growth of a few culturable cells. Chloramphenicol and ampicillin totally inhibited resuscitation of the nonculturable cells when added to samples that had been at room temperature for up to 24 h. After 72 h of resuscitation, the inhibitors had an easily detectable but reduced effect on the resuscitated cells, indicating that protein and peptidoglycan synthesis were still ongoing. Major changes in the morphology of the cells were discovered. Nonculturable cells of V. vulnificus were small cocci (approximately 1.0 micron in diameter). Upon resuscitation, the cells became large rods with a size of mid-log-phase cells (3.0 microns in length). Four days after the cells had become fully resuscitated, the cell size had decreased to approximately 1.5 micron in length and 0.7 micron in width. The cells were able to go through at least two cycles of nonculturability and subsequent resuscitation without changes in the total cell count. This is the first report of resuscitation, without the addition of nutrient, of nonculturable cells, and it is suggested that temperature may be the determining factor in the resuscitation from this survival, or adaptation, state of certain species in estuarine environments.     

Induction and resuscitation of viable nonculturable Arcobacter butzleri cells

Two strains of Arcobacter butzleri, ATCC 49616 and an environmental isolate, became nonculturable in seawater microcosms at 4 degrees C by 20 days and at room temperature by 14 days. Nonculturable cells were viable for up to 270 days of incubation in microcosms. Resuscitation of A. butzleri cells from microcosms at both temperatures was achieved 9 days after nutrient addition.     

Viable but nonrecoverable stage of Salmonella enteritidis in aquatic systems

An environmental isolate (13- 1BB ) of Salmonella enteritidis serogroup C1 was inoculated into sterile Potomac River water microcosms to observe survival and culturability of the organism by employing acridine orange direct count, fluorescent antibody direct count, direct viable count, plate count on veal infusion agar and xylose lysine decarboxylase agar, and indirect enumeration by the most-probable-number method (MPN), using media selective for Salmonella. Loss of culturability on laboratory media was observed within 48 h. However, cultures could be "resuscitated" and cultured on solid media, following addition of nutrients to the microcosms . Cells, resuscitated 4 days after apparent "die-off" (0 colony-forming units (cfu)/mL) using plate count techniques, yielded numbers of cfu in the same order of magnitude as had been observed before the onset of nutrient limitation. Microscopic techniques for direct viable counting indicated that viability is maintained for as long as 60 days after depletion of nutrients, although attempts to culture these cells, by addition of nutrient, after 21 days yielded apparently sterile plates. Thus, longer periods of "dormancy" appear to require conditions other than simple nutrient addition for resumption of cell growth and division.     

Effects of microcosm salinity and organic substrate concentration on production of Vibrio cholerae enterotoxin

The effects of aquatic processes on production of cholera toxin by Vibrio cholerae were studied with seawater microcosms. Several salinity and organic nutrient concentrations were employed. At 10 g of organic nutrient per liter of seawater, toxin production increased as the salinity was increased. At lower organic nutrient concentrations, toxin production was markedly enhanced when the salinity was 20 and 25%. Toxin concentration increased with salinity, independent of cell concentration and toxin stability. From the results obtained in this study, it is concluded that physical and chemical parameters of the aquatic environment affect not only the physiological state of V. cholerae, but also its potential pathogenicity.     

Effects of microcosm salinity and organic substrate concentration on production of Vibrio cholerae enterotoxin.

The effects of aquatic processes on production of cholera toxin by Vibrio cholerae were studied with seawater microcosms. Several salinity and organic nutrient concentrations were employed. At 10 g of organic nutrient per liter of seawater, toxin production increased as the salinity was increased. At lower organic nutrient concentrations, toxin production was markedly enhanced when the salinity was 20 and 25%. Toxin concentration increased with salinity, independent of cell concentration and toxin stability. From the results obtained in this study, it is concluded that physical and chemical parameters of the aquatic environment affect not only the physiological state of V. cholerae, but also its potential pathogenicity.     

Dormancy as a survival strategy of the fish pathogen Streptococcus parauberis in the marine environment

The fate of Streptococcus parauberis in seawater and sediment microcosms at different temperatures (6 and 22 degrees C) was investigated by comparing the survival dynamics of 2 strains of this bacterial species, isolated respectively from diseased turbot and cattle. The turbot and the bovine isolate showed similar survival kinetics, remaining culturable for approximately 1 mo in water and 6 mo in sediment. A slight influence of temperature on the stability of the cells was observed, in that the number of culturable cells was about 1 log10 unit higher at 6 than at 22 degrees C. During the starvation period, the metabolic activity of the cells, after suffering a strong reduction during the first 12 d, stabilized at levels ranging from 20 to 40% of the initial values. However, in all the microcosms, the acridine orange (AO) and 4',6-diamidino-2-phenilindole (DAPI) counts remained at about 10(5) cells ml(-1) throughout the experimental period, even when cells became undetectable by standard plate count methods. The addition of fresh medium to microcosms containing nonculturable cells induced the return to culturability of S. parauberis strains. On the basis of these results, it seems that S. parauberis has the ability to enter into a viable but nonculturable (VBNC) state. Dormant cells of the turbot isolate maintained their infectivity and pathogenic potential for fish.     

微生物在水环境中的存活和生长

在灭菌自来水模拟水体中,研究了7种细菌的存活和生长规律。Klebsiella pneumo-niae,Enterobacter aerogenes,Agrobacterium tumefatciens,在7天内平板计数降至0,而水体中镜检细菌总数(AODC)和活菌直接计数(DVC)结果无大变化,说明细菌已变成活的非可培养状态。Micrococcus,flavus 和 Streptococcus faecalis 的可培养菌数也可降至0。Pseudomonas sp.在48小时内由10~5降至10~2cfu/ml,随即升至10~6 cfu/ml 并持续到实验终了(41天)。Bacillus subtilis 在48小时平板计数降至10~2cfu/ml 并维持在该水平至实验结束(38天)。研究结果表明仅用涂布平板法检测多种细菌在水环境中的生存和分布是不合适的。     

Influence of prior growth conditions on low nutrient response of Escherichia coli in seawater

By use of experimental microcosms, it was demonstrated that the survival of Escherichia coli in nutrient-free seawater depended on the age of cells and on some physicochemical conditions during their prior growth. Cells grown in a bacteriological medium, with an acid or an alkaline pH, at high temperature (44 degrees C), or in the absence of oxygen were more sensitive to exposure to seawater of low nutrient content. In contrast, some complex media allowed production of cells adapting more rapidly to seawater. Cells grown in urine were far more sensitive than those grown in all bacteriological media tested. The sensitivity of all cells was highest when they were harvested during the early exponential phase of growth.     

Viability of the nonculturable Vibrio cholerae O1 and O139

Vibrio cholerae is capable of transforming into a viable but nonculturable (VBNC) state, and, in doing so, undergoes alteration in cell morphology. In the study reported here, Vibrio cholerae O1 and O139 cells were maintained in laboratory microcosms prepared with 1% Instant Ocean and incubated at 4 degrees C, i.e., conditions which induce the VBNC state. Cells were fixed at different stages during entry into the VBNC state and, when no growth was detectable on solid or in liquid media, the ultrastructure of these cells was examined, using both transmission and scanning electron microscopy. As shown in earlier studies, the cells became smaller in size and changed from rod to ovoid or coccoid morphology, with the central region of the cells becoming compressed and surrounded by denser cytoplasm. Because the coccoid morphology, indicative of the VBNC state is common for Vibrio cholerae in the natural environment, as well as in starved cells (Baker et al., 1983; Hood et al., 1986) viability of the coccoid, viable but nonculturable cell was investigated. The percentage of coccoid (VBNC) cells showing metabolic activity and retention of membrane integrity was monitored using direct fluorescence staining (LIVE/DEAD BacLight Bacterial Viability kit), with 75 to 90% of the viable but nonculturable coccoid cells found to be metabolically active by this test. Furthermore, the proportion of actively respiring cells, using the redox dye, 5-cyano-2, 3-ditolyl tetrazolium chloride (CTC), relative to total cells, the latter determined by DAPI staining, ranged from 10 to 50%. VBNC coccoid cells retained the antigenic determinants of Vibrio cholerae O1 and O139, respectively, evidenced by positive reaction with monoclonal fluorescent antibody. Viability was further established by susceptibility of the VBNC cells to chlorine, copper sulfate, zinc sulfate, and formaldehyde. Since retention of cell membrane integrity is a determining characteristic of viable cells, DNA was extracted from VBNC cells in microcosms maintained for two months and for one year. Conservation of cholera toxin and toxin-associated genes, ctxA, toxR, tcpA, and zot in chromosomal DNA of VBNC cells was demonstrated using PCR and employing specific primers. It is concluded that not only do VBNC V cholerae O1 and O139 retain viability up to one year, but genes associated with pathogenicity are retained, along with chromosomal integrity.     

Starvation-Survival Physiological Studies of a Marine Pseudomonas sp

Starved cultures of a marine Pseudomonas sp. showed a 99.9% decrease in viable cell count during the first 25 days of starvation, yet the culture maintained 10 viable cells per ml for over 1 year. The physiological responses of populations of a marine Pseudomonas sp. to nutrient starvation were observed for periods of up to 40 days. At various intervals during starvation, the numbers of total, viable, and respiring cells were determined within the cultures. The ATP content, endogenous respiration rate, uptake rates, and percent respiration for exogenous glucose and glutamate were determined throughout the starvation period to characterize the physiological changes in the cells. It was observed that, after initial adjustment periods, all parameters tested reached stabilized states after 18 to 25 days of starvation. The results indicate that the actively respiring subpopulation, rather than the viable or total cell numbers, is the most appropriate denominator for interpretation of observed activities on an individual cell basis.     

Temperature effects on the viable but non-culturable state of Vibrio vulnificus

Abstract The non-culturable state of Vibrio vulnificus , strain C7184, was studied in artificial seawater microcosms held at 5, 10, 15, 20, and 30°C. Plate counts were made on a non-selective medium, total cell counts were monitored by acridine orange epifluorescence, and direct viable counts (DVSs) by the method of Kogure et al. (Can J. Microbiol. 25, 415–420; 1986) and by the INT method. From an initial inoculum of 10⁷ cells/ml, V. vulnificus became non-culturable within 40 days at 5°C, although both indicators of viability revealed a viable population exceeding 10⁶ cells/ml. Cells at all higher temperatures remained culturable (at least 10⁴/ml) throughout the study. The non-culturable states of the opaque and translucent colony variants of V. vulnificus , as well as those of six other clinical and environmental strains of V. vulnificus , were examined at 5°C; all but one strain and both colony variants also became non-culturable within 40 days. In contrast, six other Vibrio spp. ( V. cholerae, V. mimicus, V. parahaemolyticus, V. natriegens, V. proteolyticus , and V. campbelli ) remained culturable at 5°C. Thus, entrance of V. vulnificus into the non-culturable state appears to be highly temperature dependent and, among the vibrios, this species may be especially sensitive to low temperature. The public health aspects of these findings are discussed.     

Characterization and resuscitation of viable but nonculturable <Emphasis Type="Italic">Vibrio alginolyticus</Emphasis> VIB283

The aim of this study was to investigate the viable but nonculturable (VBNC) state of the bacterium. Vibrio alginolyticus VIB283 was cultured in sterilized seawater microcosm at 4°C. Culturability of the cells in the microcosm was monitored by spread plate count (PC) on 2216E agar, PCs declined to undetectable levels (<0.1 CFU/ml) within 90 days. Total cell counts remained constant throughout the period as determined by acridine orange direct count (AODC). The direct viable counts, on the other hand, declined from 10¹⁰ to 10⁹ CFU/ml active cells and remained fairly constant at this level by direct viable count (DVC), which indicated that a large population of cells entered into the VBNC state. The VBNC cells could be resuscitated by temperature upshift with and without the presence of nutrition. The resuscitated time were 16 h and 8 days respectively. The resuscitation was not achieved in chick embryos. The morphology of the VBNC, normal and resuscitated cells was studied with scanning electron microscope and flow cytometry. The cells changed from rod or arc to coccoid and decreased in size when entered into the VBNC state. The resuscitated and the normal cells had almost no morphological differences.     

A combined microcosm and mesocosm approach to examine factors affecting survival and mortality of Pseudomonas fluorescens Ag1 in seawater

Abstract: The survival of Pseudomonas fluorescens Ag1 in seawater of Roskilde Fjord (Denmark) was evaluated by a series of laboratory microcosm and field-based mesocosm experiments. In sterile seawater microcosms, culturability of Ag1 was negatively influenced by high salinity (34 versus 8.5‰). In microcosms with 0.2 μm-filtered seawater, addition of a carbon + nitrogen + phosphorus nutrient mixture was needed to induce proliferation of Ag1. In nutrient-amended microcosms the Ag1 population maintained viability, as determined by the direct viable counts method, at a level close to 100%. In natural water microcosms, Ag1 decreased by two to three orders of magnitude in three days. Field experiments in 5300-litre seawater enclosures demonstrated a less pronounced decline. The observed average decline rate agreed well with the calculated average predation potential of heterotrophic nanoflagellates using fluorescence-labelled Ag1 as prey. During the experiment, mesocosms were amended with nutrients as in microcosms to attempt induction of Ag1 cell proliferation in situ, but the decrease rate of Ag1 remained unchanged. Viability remained above 25% throughout the experiment, emphasizing that the decline of Ag1 did not result from extensive cell death. The combination of micro and mesocosms proved useful as a test scenario for fate studies of microorganisms introduced into an aquatic environment.     

Survival of Salmonella Species in River Water

The survival of four Salmonella strains in river water microcosms was monitored by culturing techniques, direct counts, whole-cell hybridization, scanning electron microscopy, and resuscitation techniques via the direct viable count method and flow cytometry. Plate counts of bacteria resuspended in filtered and untreated river water decreased several orders of magnitude within the first week of incubation, while they did not decrease as rapidly in autoclaved water. In situ hybridization studies suggested a rapid decrease in ribosomal content, as determined by the drastic decrease in the number of detectable cells after 72 h. In contrast, direct counts remained relatively constant during 45 days in all microcosoms. Although the culturable counts of two bacterial strains in filtered water after 31 days represented approximately 0.001% of the total counts, direct viable counts and resuscitation studies with a dilution series suggested that the number of viable bacteria was at least four orders of magnitude higher. Additionally, notable changes in forward scatter and in nucleic acid content were observed only after 4 h of nutrient amendments by flow cytometry. However, cells from the resuscitation experiments did not grow on solid media unless cell-free supernatant from viable cultures was added during the resuscitation period. The results in this study suggest the presence of a not immediately culturable status in Salmonella. Received: 20 October 1999 / Accepted: 10 January 2000     

Starvation-Survival Physiological Studies of a Marine Pseudomonas sp.

Starved cultures of a marine Pseudomonas sp. showed a 99.9% decrease in viable cell count during the first 25 days of starvation, yet the culture maintained 10⁵ viable cells per ml for over 1 year. The physiological responses of populations of a marine Pseudomonas sp. to nutrient starvation were observed for periods of up to 40 days. At various intervals during starvation, the numbers of total, viable, and respiring cells were determined within the cultures. The ATP content, endogenous respiration rate, uptake rates, and percent respiration for exogenous glucose and glutamate were determined throughout the starvation period to characterize the physiological changes in the cells. It was observed that, after initial adjustment periods, all parameters tested reached stabilized states after 18 to 25 days of starvation. The results indicate that the actively respiring subpopulation, rather than the viable or total cell numbers, is the most appropriate denominator for interpretation of observed activities on an individual cell basis.     

Entry of Vibrio harveyi and Vibrio fischeri into the viable but nonculturable state

AIMS: Physiological responses of marine luminous bacteria, Vibrio harveyi (ATCC 14216) and V. fischeri (UM1373) to nutrient-limited normal strength (35 ppt iso-osmolarity) and low (10 ppt hypo-osmolarity) salinity conditions were determined. METHODS AND RESULTS: Plate counts, direct viable counts, actively respiring cell counts, nucleoid-containing cell counts, and total counts were determined. Vibrio harveyi incubated at 22 degrees C in nutrient-limited artificial seawater (ASW) became nonculturable after approximately 62 and 45 d in microcosms of 35 ppt and 10 ppt ASW, respectively. In contrast, V. fischeri became nonculturable at approximately 55 and 31 d in similar microcosms. Recovery of both culturability and luminescence of cells in the viable but nonculturable state was achieved by addition of nutrient broth or nutrient broth supplemented with a carbon source, including luminescence-stimulating compounds. Temperature upshift from 22 degrees C to 30 degrees C or 37 degrees C did not result in recovery from nonculturability. CONCLUSIONS: The study confirms entry of V. harveyi and V. fischeri into the viable but nonculturable state under low-nutrient conditions and demonstrates nutrient-dependent resuscitation from this state. SIGNIFICANCE AND IMPACT OF THE STUDY: This study confirms loss of luminescence of V. harveyi and V. fischeri on entry into the viable but nonculturable state and suggests that enumeration of luminescent cells in water samples may be a rapid method to deduce the nutrient status of a water sample.     

Starvation survival of the fish pathogen Aeromonas salmonicida in seawater

Abstract Three strains of the fish pathogenic bacterium Aeromonas salmonicida were examined with respect to their ability to survive in seawater. Five to seven days after plate counts decreased below the detection limit of 10 cells/ml, the population of respiring A. salmonicida cells comprised less than 4% of the initial total bacterial population. At this stage, samples were transferred either to sterile nutrient or to control flasks containing sterile nutrient-free medium. The addition of nutrients caused reappearance of growing bacteria, detected by plating on agar medium and an increase of the population of respiring bacteria to 85–95% of the total population. In a separate experiment it was shown that after more than six months of starvation at 15°C, a few of the starved A. salmonicida cells were able to regrow in liquid media after addition of nutrients, but not on agar media. These cells evade detection by direct microscopic respiratory measurement but appear to be reactivated after addition of nutrients.     

Role of cyanobacteria in the persistence of Vibrio cholerae O139 in saline microcosms

Recently, a new strain of cholera, Vibrio cholerae O139, has emerged as an epidemic strain, but there is little information about its environmental reservoir. The present investigation was aimed to determine the role of cyanobacteria in the persistence of V. cholerae O139 in microcosms. An environmental isolate of V. cholerae O139 and three cyanobacteria (Anabaena sp., Nostoc sp., and Hapalosiphon sp.) were used in this study. Survival of culturable V. cholerae O139 in microcosms was monitored using taurocholate-tellurite gelatin agar medium. Viable but nonculturable V. cholerae O139 were detected using a fluorescent antibody technique. Vibrio cholerae O139 could be isolated for up to 12 days in a culturable form in association with cyanobacteria but could not be isolated in the culturable form after 2 days from control water without cyanobacteria. The viable but nonculturable V. cholerae O139 could be detected in association with cyanobacteria for up to 15 months. These results, therefore, suggest that cyanobacteria can act as a long-term reservoir of V. cholerae O139 in an aquatic environment.     

Starvation survival of Gordonia polyisoprenivorans CCT 7137, isolated from contaminated groundwater in Brazil

Gordonia polyisoprenivorans CCT7137, exopolysaccharide-producing bacterium, was isolated from groundwater contaminated with leachate in a former municipal landfill site (São Paulo, Brazil). The strain was submitted to starvation in phosphate-buffered saline solution for 56 days so as to evaluate its behavior regarding cuturability and cell morphology. As a response to starvation, G. polyisoprenivorans CCT7137 presented reduction in viable cell count, cell size and cell shape alteration. The initial number of viable cells was 1.51 × 10⁷ c.f.u. ml. After 7 days of starvation culturability dropped to 13.70% (2.07 × 10⁶ c.f.u/ml) and, after 56 days, to 3.25% (4.93 × 10⁵ c.f.u/ml). It was also observed that after 7 days of starvation the cell size presented an average reduction in the values of length, length/width ratio, volume and area of 50, 58, 40 and 42%, respectively. The length/width ratio showed a change of shape from rod to coccobacillus. Changes in cell dimensions and distribution of cell into classes were not significant after day 7 of starvation. The results obtained show that it is not necessary for the strain to starve for more than a week to obtain G. polyisoprenivorans CCT7137 size- reduced cells. The results also indicate the potential for its starved forms to be used in future tests in porous medium to study the production of exopolysaccharide in situ.