Rapid selective enumeration of bacteria in foods using a microcolony epifluorescence microscopy technique

The growth patterns of macrocolonies of 59 different pure cultures were studied on eight selective solid media. A method of growing microcolonies on the surface of polycarbonate membrane filters, placed on the selective agar media, followed by staining and examination by epifluorescent microscopy was developed. The patterns of growth of the pure cultures as microcolonies were studied on the eight selective media. Only four media proved to be reliable for this purpose and the relationship between the microcolony count and plate count was studied on these media together with nutrient agar. Microcolony counts using three of these media (enriched lauryl sulphate aniline blue, pseudomonas selective agar (C-F-C) and Baird-Parker medium) were capable of giving reliable estimates of coliforms (r = 0·89), pseudomonads (r = 0·93) and staphylococci (r = 0·92) after incubation at 30°C for 3 or 6 h (staphylococci) at contamination levels of above 10³ bacteria/g in a variety of foods. The results are available within a working day and should allow the more efficient management of food supplies.     

Rapid selective enumeration of bacteria in foods using a microcolony epifluorescence microscopy technique

The growth patterns of microcolonies of 59 different pure cultures were studied on eight selective solid media. A method of growing microcolonies on the surface of polycarbonate membrane filters, placed on the selective agar media, followed by staining and examination by epifluorescent microscopy was developed. The patterns of growth of the pure cultures as microcolonies were studied on the eight selective media. Only four media proved to be reliable for this purpose and the relationship between the microcolony count and plate count was studied on these media together with nutrient agar. Microcolony counts using three of these media (enriched lauryl sulphate aniline blue, pseudomonas selective agar (C-F-C) and Baird-Parker medium) were capable of giving reliable estimates of coliforms (r = 0.89), pseudomonads (r = 0.93) and staphylococci (r = 0.92) after incubation at 30 degrees C for 3 or 6 h (staphylococci) at contamination levels of above 10(3) bacteria/g in a variety of foods. The results are available within a working day and should allow the more efficient management of food supplies.     

Detection of viable, but non-culturable Pseudomonas fluorescens DF57 in soil using a microcolony epifluorescence technique

Abstract Kanamycin-resistant Pseudomonas fluorescens DF57-3 cells (Tn5 modified) inoculated in soil microcosms rapidly lost their culturability, as defined by visible colony formation on Kings B agar supplemented with kanamycin. Thus, after 40 days only 0.02–0.35% of the initial inoculum was culturable. A microcolony epifluorescence technique was developed to determine the viable, but non-culturable subpopulation. A suspension of bacteria from the soil was prepared in salt solution after a sonication procedure and a sample was filtered onto a 0.2 μm Nuclepore filter. The filter was then placed for 3–4 days on the surface of Kings B agar before staining with acridine orange for epifluorescence microscopy. By staining and washing the filters carefully, disruption of microcolonies could be avoided. A majority of the microcolonies resulted from 2–3 cell divisions during the first 2 days of the incubation period, after which the cell divisions stopped. These microcolonies were taken to represent a population of viable, but non-culturable cells and comprised about 20% of the initial inoculum. A similar recovery was obtained when the filters were incubated on the surface of citrate minimal medium or soil extract medium. A few microcolonies showed continued growth on the filters, however, and their number corresponded well with that of visible macrocolonies. Observation by microscopy of a few (2–3) cell divisions (microcolony epifluorescence technique) is proposed for determination of subpopulations of viable, but non-culturable bacteria in soil.     

Cultivating previously uncultured soil bacteria using a soil substrate membrane system

Most bacteria are recalcitrant to traditional cultivation in the laboratory. The soil substrate membrane system provides a simulated environment for the cultivation of previously undescribed soil bacteria as microcolonies. The system uses a polycarbonate membrane as a solid support for growth and soil extract as the substrate. Diverse microcolonies can be visualized using total bacterial staining combined with fluorescence in situ hybridization (FISH) after 7-10-d incubation. Molecular typing shows that the majority of microcolony-forming bacteria recovered using this protocol were resistant to growth using standard methods. The protocol takes <4 h of bench time over the 10-d period.     

The Bacteroides glycocalyx as visualized by differential interference contrast microscopy

The glycocalyx of eight strains representing six species of Bacteroides was examined by differential interference contrast microscopy. Wet mounts in India ink were prepared from bacteria cultured in broth and on an agar medium; the wet mounts were observed by phase-contrast microscopy and differential interference contrast microscopy. With differential interference contrast microscopy, all bacteria demonstrated a glycocalyx, which included capsules surrounding single cells and microcolonies, strands of glycocalyx connecting cells and microcolonies, detached slime, and solid masses of glycocalyx in which innumerable bacteria were enmeshed. Bacteria showed comparable amounts of glycocalyx by visual observation with differential interference contrast microscopy whether grown on plates or in broth. Serial transfers of cultures did not diminish the amount of glycocalyx. Differential interference contrast microscopy proved to be a superior method to phase contrast for examining wet preparations of Bacteroides.     

Microcultural Study of Bacterial Size Changes and Microcolony and Ultramicrocolony Formation by Heterotrophic Bacteria in Seawater

With a microculture technique and time-lapse, phase-contrast photomicrography, it was possible to follow the division of individual cells and the development of microcolonies of bacteria in freshly collected marine water samples. A certain number of marine bacteria, upon inoculation onto a nutrient rich agar surface, displayed an increase in size as well as a high growth rate. Other bacteria were identified as very small marine bacteria (ultramicrobacteria). These had a very slow growth rate when inoculated onto a nutrient-rich agar surface. These latter cells formed very small microcolonies (ultramicrocolonies), and cell size did not increase significantly. These two types of marine heterotrophs could be described in terms of zymogenous and autochthonous bacteria, a concept used by Winogradsky for describing soil microorganisms.     

Viability of Indigenous Soil Bacteria Assayed by Respiratory Activity and Growth

The bacterial population in barley field soil was estimated by determining the numbers of (i) cells reducing the artificial electron acceptor 5-cyano-2,3-ditolyl tetrazolium chloride (CTC) to CTC-formazan (respiratory activity), (ii) cells dividing a limited number of times (microcolony formation) on nutrient-poor media, (iii) cells dividing many times (colony formation) on nutrient-poor agar media, and (iv) cells stained with acridine orange (total counts). The CTC reduction assay was used for the first time for populations of indigenous soil bacteria and was further developed for use in this environment. The number of viable cells was highest when estimated by the number of microcolonies developing during 2 months of incubation on filters placed on the surface of nutrient-poor media. The number of bacteria reducing CTC to formazan was slightly lower than the number of bacteria forming microcolonies. Traditional plate counts of CFU (culturable cells) yielded the lowest estimate of viable cell numbers. The microcolony assay gave an estimate of both (i) cells forming true microcolonies (in which growth ceases after a few cell divisions) representing viable but nonculturable cells and (ii) cells forming larger microcolonies (in which growth continues) representing viable, culturable cells. The microcolony assay, allowing single-cell observations, thus seemed to be best suited for estimation of viable cell numbers in soil. The effect on viable and culturable cell numbers of a temperature increase from 4 to 17°C for 5 days was investigated in combination with drying or wetting of the soil. Drying or wetting prior to the temperature increase, rather than the temperature increase per se, affected both the viable and culturable numbers of bacteria; both numbers were reduced in predried soil, while they increased slightly in the prewetted soil.     

Oligotrophic Bacterioplankton with a Novel Single-Cell Life Strategy

A large fraction of the marine bacterioplankton community is unable to form colonies on agar surfaces, which so far no experimental evidence can explain. Here we describe a previously undescribed growth behavior of three non-colony-forming oligotrophic bacterioplankton, including a SAR11 cluster representative, the world's most abundant organism. We found that these bacteria exhibit a behavior that promotes growth and dispersal instead of colony formation. Although these bacteria do not form colonies on agar, it was possible to monitor growth on the surface of seawater agar slides containing a fluorescent stain, 4′,6′-diamidino-2-phenylindole (DAPI). Agar slides were prepared by pouring a solution containing 0.7% agar and 0.5 μg of DAPI per ml in seawater onto glass slides. Prompt dispersal of newly divided cells explained the inability to form colonies since immobilized cells (cells immersed in agar) formed microcolonies. The behavior observed suggests a life strategy intended to optimize access of individual cells to substrates. Thus, the inability to form colonies or biofilms appears to be part of a K-selected population strategy in which oligotrophic bacteria explore dissolved organic matter in seawater as single cells.     

Quantitation of Adsorption of Rhizobia in Low Numbers to Small Legume Roots

Bacteria adsorbed in low numbers to alfalfa or clover root surfaces were counted after incubation of seedlings in mineral solution with very dilute inocula (less than 10⁵ bacteria per ml) of an antibiotic-resistant strain under defined conditions. After specified washing, bacteria which remained adsorbed to roots were selectively quantitated by culturing the roots embedded in yeast extract-mannitol-antibiotic agar and counting the microcolonies along the root surface; the range was from about 1 bacterium per root (estimated as the most probable number) to 50 bacteria per cm of root length (by direct counting). This simple procedure can be used with any pair of small-rooted plant and antibiotic-resistant bacterium, requires bacterial concentrations comparable to those frequently found in soils, and yields macroscopic localization and distribution data for adsorbed bacteria over the root surface. The number of adsorbed bacteria was proportional to the size of the inoculum. One of every four Rhizobium meliloti cells adsorbed in very low numbers to alfalfa roots resulted in the formation of a nodule. Overall adsorption of various symbiotic and nonsymbiotic bacterial strains to alfalfa and clover roots did not reflect the specificities of these legumes for their respective microsymbionts, R. meliloti and R. trifolii.     

Escherichia coli K-12 cell-cell interactions seen by time-lapse video.

The high degree of organization in mature bacterial colonies suggests specific interactions between the cells during colony development. We have used time-lapse video microscopy to find evidence for cell-cell interactions. In its initial stages, Escherichia coli K-12 colony morphogenesis displayed control of the geometry of cell growth and involved intimate side-by-side associations. When microcolonies developed from isolated single bacteria, a directed process of elongation and division resulted in the appearance of a symmetrical four-cell array. When growth began with separate but nearby bacteria, the daughters of different cells elongated towards each other and also lined up side by side. Interactions between microcolonies containing several hundred or more bacteria were visible several hours later. Control of cell morphogenesis at later stages of microcolony development was strain specific. These results show that E. coli K-12 cells respond to each other and adjust their cellular morphogenesis to form multicellular groups as they proliferate on agar.     

Oligotrophic bacterioplankton with a novel single-cell life strategy

A large fraction of the marine bacterioplankton community is unable to form colonies on agar surfaces, which so far no experimental evidence can explain. Here we describe a previously undescribed growth behavior of three non-colony-forming oligotrophic bacterioplankton, including a SAR11 cluster representative, the world's most abundant organism. We found that these bacteria exhibit a behavior that promotes growth and dispersal instead of colony formation. Although these bacteria do not form colonies on agar, it was possible to monitor growth on the surface of seawater agar slides containing a fluorescent stain, 4',6'-diamidino-2-phenylindole (DAPI). Agar slides were prepared by pouring a solution containing 0.7% agar and 0.5 micro g of DAPI per ml in seawater onto glass slides. Prompt dispersal of newly divided cells explained the inability to form colonies since immobilized cells (cells immersed in agar) formed microcolonies. The behavior observed suggests a life strategy intended to optimize access of individual cells to substrates. Thus, the inability to form colonies or biofilms appears to be part of a K-selected population strategy in which oligotrophic bacteria explore dissolved organic matter in seawater as single cells.     

Viability of soil bacteria: Optimization of plate-counting technique and comparison between total counts and plate counts within different size groups

Viable counts of heterotropic soil bacteria were 3–5 times higher on low-nutrient agar media compared with a series of conventional agar media. Substantial amounts of monosaccharides and amino acids were present in solid media made from distilled water and agar powder, and a salt-solution agar medium (without organic substrates added) gave practically the same colony counts as the low nutrient soil extract agar medium. MPN values were comparable to or lower than plate counts. A search for slow-growing cells in the negative MPN tubes by fluorescence microscopical examination after 3 months incubation was negative.The viable counts were 2–4% of the total microscopical counts in different soils. Assuming that the colony-forming cells did not derive from the numerous dwarf cells present in soil, a calculated percent viability of the larger cells was about 10%. The ecological significance of the plate-counting technique is discussed.     

Enrichment culture and isolation of slow-growing bacteria

 Enrichment containing large numbers of slow-growing bacteria was developed by repeated batch culture under high biomass concentrations (more than 10 000 mg biomass/l). The characteristics of slow-growing bacterial populations were elucidated by application of colony-forming-curve (CFC) analysis. The CFC were obtained by counting the number of visible colonies on agar plates at successive intervals. The enrichment consisted of several groups with different colony-forming rates and the slow-growing bacteria appeared on cell extract/agar plates after 7 days of incubation. It was found that large numbers of slow-growing bacteria survived under starvation conditions. One of the slow colony-forming bacteria, strain TI-X7, was tentatively identified as being of the genus Micrococcus. The enrichment contained a large amount of Micrococcus-like tetrad cells. The dialysate fractions in excess cell extract, permeable through dialysis tubing, were extremely effective for growth of strain TI-X7. Received: 15 December 1995/Accepted: 20 February 1996     

Evaluation of levofloxacin antitubercular activity in vitro and in lung tissue culture]

Levofloxacin in vitro demonstrated bactericidal effect against susceptible and multi-drug resistant Mycobacterium tuberculosis: range of MICs was 0.25-0.5 mcg/mL, MBC-0.5-1.0 mcg/mL. Postantibiotic effect after 24-hour exposition to bactericidal concentrations was 35-39 days. Levofloxacin possesed low toxicity when tested in mice lungs tissue culture--maximum safety concentration was 50 mcg/mL. Bactericidal effect of levofloxacin started three days after exposition and was maximal by 7 days of incubation: by this time mycobacterial microcolonies destruction started with detritus formation. It is emphasized that lung cells kept their viability completely. Combination of levofloxacin with isoniazide or pirazinamide resulted in strong synergistic effect obvious after 5 days of incubation, mycobacterial colonies destruction was registered by 7th day. Combination of levofloxacin with rifampicin resulted in antagonistic effect obvious by 7th day of the contact: the resulting effect was statistically significant and was manifested as microcolonies number and size enlargement when compared to data for single levofloxacin.     

Green Fluorescent Protein-Marked Pseudomonas fluorescens: Localization, Viability, and Activity in the Natural Barley Rhizosphere

The gfp-tagged Pseudomonas fluorescens biocontrol strain DR54-BN14 was introduced into the barley rhizosphere. Confocal laser scanning microscopy revealed that the rhizoplane populations of DR54-BN14 on 3- to 14-day-old roots were able to form microcolonies closely associated with the indigenous bacteria and that a majority of DR54-BN14 cells appeared small and almost coccoid. Information on the viability of the inoculant was provided by a microcolony assay, while measurements of cell volume, the intensity of green fluorescent protein fluorescence, and the ratio of dividing cells to total cells were used as indicators of cellular activity. At a soil moisture close to the water-holding capacity of the soil, the activity parameters suggested that the majority of DR54-BN14 cells were starving in the rhizosphere. Nevertheless, approximately 80% of the population was either culturable or viable but nonculturable during the 3-week incubation period. No impact of root decay on viability was observed, and differences in viability or activity among DR54-BN14 cells located in different regions of the root were not apparent. In dry soil, however, the nonviable state of DR54-BN14 was predominant, suggesting that desiccation is an important abiotic regulator of cell viability.     

Growth and Plating Efficiency of Methanococci on Agar Media

Plating techniques for cultivation of methanogenic bacteria have been optimized for two members of the genus Methanococcus. Methanococcus maripaludis and Methanococcus voltae were cultivated on aerobically and anaerobically prepared agar media. Maintenance of O₂ levels below 5 μl/liter within an anaerobic glove box was necessary during plating and incubation for 90% recovery of plated cells. Under an atmosphere of H₂, CO₂, and H₂S (79:20:1), 2 to 3 days of incubation at 37°C were sufficient for the formation of visible colonies. The viability of plated cells was significantly affected by the growth phase of the culture, H₂S concentration, and the volume of medium per plate. In addition, colony size of methanococci was affected by agar type, as well as by the concentrations of agar, H₂S, and bicarbonate.     

Colony formation by Helicobacter pylori after long-term incubation under anaerobic conditions

To evaluate the viability of Helicobacter pylori cultured under anaerobic conditions, H. pylori strain TK1029 was grown on blood agar in a microaerophilic environment at 37 degrees C for 4 days, and subsequently cultured under anaerobic conditions for 1 to 35 days. Colony formation by bacteria on blood agar plates cultured under anaerobic conditions was observed only for up to 4 days of microaerophilic incubation. By Gram staining, the morphological form of the bacteria was shown to be predominantly coccoid. However, bacteria cultured under anaerobic conditions for 15 to 35 days formed colonies on blood agar after pre-incubation of bacteria with PBS, but not without pre-incubation. These results suggest that H. pylori survives long-term culture under anaerobic conditions and that both pre-incubation in non-nutrient solution and high density of bacterial concentration might be important for recovery of H. pylori cultured for a prolonged time under anaerobic conditions.     

Green fluorescent protein-marked Pseudomonas fluorescens: localization, viability, and activity in the natural barley rhizosphere.

The gfp-tagged Pseudomonas fluorescens biocontrol strain DR54-BN14 was introduced into the barley rhizosphere. Confocal laser scanning microscopy revealed that the rhizoplane populations of DR54-BN14 on 3- to 14-day-old roots were able to form microcolonies closely associated with the indigenous bacteria and that a majority of DR54-BN14 cells appeared small and almost coccoid. Information on the viability of the inoculant was provided by a microcolony assay, while measurements of cell volume, the intensity of green fluorescent protein fluorescence, and the ratio of dividing cells to total cells were used as indicators of cellular activity. At a soil moisture close to the water-holding capacity of the soil, the activity parameters suggested that the majority of DR54-BN14 cells were starving in the rhizosphere. Nevertheless, approximately 80% of the population was either culturable or viable but nonculturable during the 3-week incubation period. No impact of root decay on viability was observed, and differences in viability or activity among DR54-BN14 cells located in different regions of the root were not apparent. In dry soil, however, the nonviable state of DR54-BN14 was predominant, suggesting that desiccation is an important abiotic regulator of cell viability.     

Sequence of Events in the Digestion of Fresh Legume Leaves by Rumen Bacteria

When fresh whole leaves of six different species of forage legumes were suspended in an artificial rumen medium and inoculated with rumen bacteria, bacterial adhesion and proliferation were noted at the stomata, and penetration of the stomate by these bacteria was documented by electron microscopy. The invading bacteria adhered to surfaces within the intercellular space of the leaf and produced very extensive exopolysaccharide-enclosed microcolonies. After some of the legume leaf cell walls were disorganized and ruptured by bacterial digestion, these cells (notably, parenchyma and epidermal cells) were invaded by bacteria, with subsequent formation of intracellular microcolonies. However, other cells were neither ruptured nor colonized (notably, stomata guard cells and vascular tissue). At all stages of the digestion of intact legume leaves, the rumen bacteria grew in microcolonies composed of cells of single or mixed morphological types, and a particular ecological niche was often completely and consistently occupied by a very large microcolony of cells of single or mixed morphological types.