Influence of Viable Cells on the Resuscitation of Dormant Cells in Micrococcus luteus Cultures Held in an Extended Stationary Phase: the Population Effect

A high proportion of Micrococcus luteus cells in cultures which had been starved for 3 to 6 months lost the ability to grow and form colonies on agar plates but could be resuscitated from their dormancy by incubation in an appropriate liquid medium (A. S. Kaprelyants and D. B. Kell, Appl. Environ. Microbiol. 59:3187-3196, 1993). In the present work, such cultures were studied by both flow cytometry and conventional microbiological methods and were found to contain various numbers of viable cells. Pretreatment of such cultures with penicillin G, and subsequent dilution, was used to vary this number. When the initial number of colony-forming cells per 30-ml flask was approximately nine (±five) or more, resuscitation of 10 to 40% of the cells, and thus culture growth, was observed. The lag period before the appearance of a population of cells showing significant accumulation of the fluorescent dye rhodamine 123 (i.e., of cells with measurable membrane energization) decreased from 70 to 27 h when the number of viable cells was increased from 30 to 10⁵ per flask, while the lag period before an observable increase in the number of colony-forming cells occurred was almost constant (at some 20 h). Provided there were more than nine (±five) initially viable cells per flask, the number of initially viable cells did not affect the final percentage of resuscitable cells in the culture. The lag period could be ascribed in part to the time taken to restore the membrane permeability barrier of starved cells during resuscitation, as revealed by flow cytometric assessment of the uptake of the normally membrane-impermeant fluorescent DNA stain PO-PRO-3 {4-[3-methyl-2, 3-dihydro-(benzo-1, 3-oxazole)-2-methylidene]-1-(3′-trimethylammonium propyl)-pyridinium diiodide}. Although cell populations which contained fewer than nine ±five viable cells per flask failed to grow, 4 to 20% of the cells (of 1.2 X 10⁶) were able to accumulate rhodamine 123 after 80 to 100 h of incubation, showing the ability of a significant number of the cells in the population at least to display “metabolic resuscitation.” Resuscitation and cell growth under such conditions were favored by the use of a 1:1 mixture of fresh lactate medium and supernatant from late-logarithmic-phase M. luteus cultures as the resuscitation medium. We conclude that the presence of a small fraction of viable cells at the onset of resuscitation facilitates the recovery of the majority of the remaining (dormant) cells. The cell density dependence of the kinetics, or population effect, suggests that this recovery is due to the excretion of some factor(s) which promoted the transition of cells from a state in which they are incapable of growth and division to one in which they are capable of colony formation.     

Estimation of dormant Micrococcus luteus cells by penicillin lysis and by resuscitation in cell-free spent culture medium at high dilution

Abstract Micrococcus luteus starved for 2–7 months in spent medium following growth to stationary phase in batch culture exhibited a culturability (as estimated by direct plating on nutrient agar plates) of < 0.001%. However, following a lag, some 70% of the cells could be lysed upon inoculation into and cultivation in fresh lactate minimal medium containing penicillin, showing the capability of a significant portion of the cells at least to enlarge (and thus potentially to resuscitate). When the viable cell count was estimated using the most probable number method, by incubation of high dilutions of starved cells in liquid growth media, the number of culturable or resuscitable cells was very low, and little different from the viable cell count as assessed by plating on solid media. However, the apparent viability of these populations evidenced with the most probable number method was 1000–100 000-fold greater when samples were diluted into liquid media containing supernatants taken from the stationary phase of batch cultures of the organism, suggesting that viable cells can produce a factor which stimulates the resuscitation of dormant cells. Both approaches show, under conditions in which the growth of a limited number of viable cells during resuscitation is excluded, that a significant portion of the apparently non-viable cell population in an extended stationary phase is dormant, and not dead.     

Stimulation of the multiplication of Micrococcus luteus by an autocrine growth factor

Viable cells of Micrococcus luteus secrete a proteineous growth factor (Rpf) which promotes the resuscitation of dormant, nongrowing cells to yield normal, colony-forming bacteria. When washed M. luteus cells were used as an inoculum, there was a pronounced influence of Rpf on the true lag phase and cell growth on lactate minimal medium. In the absence of Rpf, there was no increase in colony-forming units for up to 10 days. When the inoculum contained less than 10⁵ cells ml^–1, macroscopically observable M. luteus growth was not obtained in succinate minimal medium unless Rpf was added. Incubation of M. luteus in the stationary phase for 100 h resulted in a failure of the cells to grow in lactate minimal medium from inocula of small size although the viability of these cells was close to 100% as estimated using agar plates made from lactate minimal medium or rich medium. The underestimation of viable cells by the most-probable-number (MPN) method in comparsion with colony-forming units was equivalent to the requirement that at least 10⁵ cells grown on succinate medium, 10³ cells from old stationary phase, or approximately 10–500 washed cells are required per millilitre of inoculum for growth to lead to visible turbidity. The addition of Rpf in the MPN dilutions led to an increase of the viable cell numbers estimated to approximately the same levels as those determined by colony-forming units. Thus, a basic principle of microbiology –“one cell-one culture”– may not be applicable in some circumstances in which the metabolic activity of “starter” cells is not sufficient to produce enough autocrine growth factor to support cell multiplication. Received: 7 December 1998 / Accepted: 7 April 1999     

Quantitative Analysis of the Physiological Heterogeneity within Starved Cultures of Micrococcus luteus by Flow Cytometry and Cell Sorting

A high proportion of Micrococcus luteus cells in cultures which had been starved for 3 to 6 months lost the ability to grow and form colonies on agar plates but could be resuscitated from their dormancy by incubation in an appropriate liquid medium (A. S. Kaprelyants and D. B. Kell, Appl. Environ. Microbiol. 59:3187-3196, 1993). We used flow cytometry and cell sorting to study populations of bacteria that had been starved for 5 months. These cells could be stained by the fluorescent lipophilic cation rhodamine 123, but such staining was almost independent of metabolically generated energy in that it was not affected by uncouplers. Two populations could be distinguished, one with a lower degree of rhodamine fluorescence (a degree of fluorescence referred to as region A and containing approximately 80% of the cells) and one with a more elevated degree of fluorescence (region B, approximately 20% of the cells). Subsequent incubation of starved cells in fresh medium in the presence of the antibiotic chloramphenicol (to which M. luteus is sensitive) resulted in the transient appearance of cells actively accumulating rhodamine 123 (and fluorescing in region B) and of larger cells exhibiting a yet-greater degree of fluorescence (region C). These more fluorescent cells accounted for as much as 50% of the total population, under conditions in which the viable and total counts were constant. Thus, metabolic resuscitation of at least one-half of the cells takes place under conditions in which cryptic growth cannot play any role. Sorting experiments revealed that the great majority of the viable cells in the starved population are concentrated in regions B and C and that the extent of rhodamine staining under conditions of starvation therefore reflects the physiological state of the cells. Physical separation of these cells from cells in region A resulted in an increase (of approximately 25-fold) in the viability of cells in regions B and C and of the population as a whole. Resuscitation of dormant cells in a most-probable-number assay in the presence of supernatant taken from growing M. luteus revealed the resuscitation of cells from regions B and C but not from region A. It is suggested that initially dormant (resuscitable) cells are concentrated in regions B and C.     

Cell immobilization in composite agar layer microporous membrane structures: growth kinetics of gel-entrapped cultures and cell leakage limitation by a microporous membrane

Agar discs containing different amounts of viable Escherichia coli cells (from 10 to 10⁶ organisms·g^–1 agar) were incubated in a nutrient medium and the growth of agar-entrapped bacteria and free (released) cells was monitored. The study was repeated with composite immobilized-cell structures obtained by placing a microporous membrane filter between the gel matrix and the incubation medium. In both cases, immobilized cells grew exponentially and reached a peak concentration an order of magnitude higher than that of free (suspended) cell cultures. The maximum specific growth rates of entrapped bacteria, ranging between 0.0115 min^–1 and 0.0145 min^–1, i.e., slightly higher than that of control free cultures (0.011 min^–1), showed no clear dependence on the initial cell loading (ICL). The microporous filter proved efficient in limiting cell leakage since it noticeably lengthened the leakage time at a given ICL. This efficiency, however, decreased at high ICL and high growth rate of immobilized organisms. Correspondence to: G.-A. Junter     

Biochemical changes accompanying the long-term starvation of Micrococcus luteus cells in spent growth medium

Changes in the biochemical properties of Micrococcus luteus cells were studied during the transition to a dormant state after incubation in an extended stationary phase. The overall DNA content after 150 days of starvation was similar to its initial level, while the RNA content decreased by 50%. Total lipids and protein, phospholipids and membrane proteins declined rapidly within the first 1–10 days of starvation. After 180 days of starvation, cells contained 43% of the protein and 35% of the lipid initially present. Starvation for 120 days resulted in the loss of phosphatidylglycerol and, to some extent, of phosphatidylinositol, giving a membrane whose phospholipids consisted mainly of cardiolipin. The membrane fluidity declined during starvation, as judged by diphenyl hexatriene fluorescence anisotropy measurements. Oxidase activities declined to zero within the first 20–30 days of starvation, while the dehydrogenases and cytochromes were more stable. The activities of some cytoplasmic enzymes were lost very rapidly, while NADPH-linked isocitrate dehydrogenase had 30% of its initial activity after 120 days of starvation. For all parameters tested there were significant fluctuations during the first 10–20 days of starvation, which may reflect cryptic growth in the culture.Abbreviations MPN Most probable number - DPH Diphenyl hexatriene     

Dormancy in Stationary-Phase Cultures of Micrococcus luteus: Flow Cytometric Analysis of Starvation and Resuscitation

Cultures of the copiotrophic bacterium Micrococcus luteus were stored in spent growth medium for an extended period of time following batch culture. After an initial decrease, the total cell counts remained constant at approximately 60 to 70% of the counts at the beginning of storage. The level of viability, as judged by plate counts, decreased to less than 0.05%, while respiration and the ability to accumulate the lipophilic cation rhodamine 123 decreased to undetectable levels. However, using penicillin pretreatment (to remove viable cells) and flow cytometry and by monitoring both the total and viable counts, we found that at least 50% of the cells in populations of 75-day-old cultures were not dead but were dormant. Resuscitation in liquid medium was accompanied by the appearance of a population of larger cells, which could accumulate rhodamine 123 and reduce the dye 5-cyano-2,3-ditolyl tetrazolium chloride to a fluorescent formazan, while a similar fraction of the population was converted to colony-forming, viable cells. We surmise that dormancy may be far more common than death in starving microbial cultures.     

Stevioside biosynthesis by callus,root, shoot and rooted-shoot cultures in vitro

Leaf explants of Stevia rebaudiana Bertoni (Compositae), an herb which produces the sweet ent-kaurene glycoside stevioside, were cultured in Murashige and Skoog medium with vitamins, sucrose (30 g l^–1), agar (0.9% w/v) and supplemented with naphthaleneacetic acid (NAA, 0.5 mg l^–1) and benzylaminopurine (BAP, 0.5 mg l^–1). These conditions yielded friable callus cultures. Differentiation of the callus tissue was then achieved by eliminating the agar and modulating the medium's hormone concentrations. Thus, medium containing increased auxin concentration (1.0 mg l^–1) and no cytokinin or increased cytokinin (1.0 mg l^–1) and no auxin yielded root or shoot cultures respectively. Supplementation of the shoot medium with NAA (1.0 mg ml^–1) induced shoot cultures to grow roots thereby differentiating into rooted-shoot cultures. Only the rooted-shoot cultures tasted sweet. Feedings of [2-¹⁴C]acetic acid to callus, shoot or rooted-shoot cultures demonstrated that only the rooted-shoot cultures are capable of de novo biosynthesis of the aglycone moiety of stevioside (steviol). In addition, [methyl-³H(N)steviol feedings to shoot or rooted-shoot cultures illustrated that both types of cultures are capable of the glycosylation reaction. The ability of these tissues to glycosylate steviol to stevioside was also demonstrated employing crude enzyme preparations derived from shoot or rooted-shoot cultures. These results suggest that stevioside biosynthesis is a function of tissue differentiation since both roots and leaves are required for cultured S. rebaudiana to biosynthesize stevioside from acetate, while the final biosynthetic steps can be performed at all levels of differentiation.     

Micropropagation of zedoary (<Emphasis Type="Italic">Curcuma zedoaria</Emphasis> Roscoe) – a valuable medicinal plant

Tissue culture propagation system was developed for zedoary (Curcuma zedoaria Roscoe), a valuable medicinal plant, using rhizome sprout cultures. Shoots were induced from rhizomes on basal MS medium containing 20 g l^–1 sucrose and 5 g l^–1 agar, supplemented with 20 (v/v) coconut water (CW) and benzylaminopurine (BA) concentrations from 0.5 to 5.0 m g l^–1. The excised shoots were subcultured on Murashige-Skoog (MS) medium with 20 (v/v) CW and different concentrations of BA and kinetin (Kin), either alone or in combination with indolebutyric acid (IBA) or naphthaleneacetic acid (NAA). MS medium with 20 (v/v) CW, 3 mg l^–1 BA, and 0.5 mg l^–1 IBA resulted in a multiplication rate per shoot; 5.6 shoots per explant were obtained on average after 30 days of culture. Well-developed shoots (30–40 mm in length) were rooted on MS medium containing 20 g l^–1 sucrose and 8 g l^–1 agar, supplemented with 20 (v/v) CW and 2 mg l^–1 NAA. More than 95 of the rooted plants were established in pots after hardening.     

Establishment of Orthosiphon stamineus Cell Suspension Culture for Cell Growth

Callus of Orthosiphon stamineus could be induced successfully from petiole, leaf and stem tissues but not roots when cultured on MS medium containing different concentration of NAA (0–4.0 mg l^–1) and 2,4-D (0–2.0 mg l^–1). Highest fresh weight callus production was obtained from leaf explants and those with best friability were obtained on MS medium plus 1.0 mg l^–1 2,4-D plus 1.0 mg l^–1 NAA. Cell suspension cultures were established from these cultures. The appropriate cell inoculum size for the best cell growth was 0.75 g of cells in 20 ml culture medium. Cell suspension culture using MS medium supplemented with 1.0 mg l^–1 2,4-D promoted the best cell growth with maximum biomass of 8.609 g fresh weight and 0.309 g dry weight 24 days after inoculation. Cells that grew in MS medium supplemented with 1.0 mg l^–1 2,4-D reached the stationary growth phase in 15 days as compared to the cells that grew in MS medium supplemented with 1.0 mg l^–1 2,4-D + 1.0 mg l^–1 NAA reached the stationary phase in 24 days. MS medium supplemented with 1.0 mg l^–1 2,4-D was considered as the maintenance medium for maintaining the optimum cell growth of O. stamineus in the cell suspension cultures with 2-week interval subculture.     

Evaluation of Rpf protein of Micrococcus luteus for cultivation of soil actinobacteria

Rpf protein, a kind of resuscitation promoting factor, was first found in the culture supernatant of Micrococcus luteus. It can resuscitate the growth of M. luteus in “viable but non-culture, VBNC” state and promote the growth of Gram-positive bacteria with high G + C content. This paper investigates the resuscitating activity of M. luteus ACCC 41016^T Rpf protein, which was heterologously expressed in E. coli, to cells of M. luteus ACCC 41016^T and Rhodococcus marinonascens HBUM200062 in VBNC state, and examines the effect on the cultivation of actinobacteria in soil. The results showed that the recombinant Rpf protein had resuscitation effect on M. luteus ACCC 41016^T and R. marinonascens HBUM200062 in VBNC state. 83 strains of actinobacteria, which were distributed in 9 families and 12 genera, were isolated from the experimental group with recombinant Rpf protein in the culture medium. A total of 41 strains of bacteria, which were distributed in 8 families and 9 genera, were isolated from the control group without Rpf protein. The experimental group showed richer species diversity than the control group. Two rare actinobacteria, namely HBUM206391^T and HBUM206404^T, were obtained in the experimental group supplemented with Rpf protein. Both may be potential new species of Actinomadura and Actinokineospora, indicating that the recombinant expression of M. luteus ACCC 41016^T Rpf protein can effectively promote the isolation and culture of actinobacteria in soil.     

On resuscitation from the dormant state of Micrococcus luteus

It has been found previously that a significant number of Micrococcus luteus cells starved in a prolonged stationary phase (up to 2 months) and then held on the bench at room temperature without agitation for periods of up to a further 2–7 months can be resuscitated in liquid media which contained (statistically) no initially-viable (colony-forming) cells but which were fortified with sterile supernatant from the late logarithmic phase of batch growth. Here it was found that such resuscitation can be done only within a defined time period after taking the first sample from such cultures, necessarily involving agitation of the cells. The duration of this period depends on the age of the starved culture: cells kept on the bench for 3 months possess a 2 month period of resuscitability while cells starved for 6 months can be resuscitated only within 10 days after the beginning of sampling. It is suggested that the input of oxygen to the starved cultures while they are agitated may exert a negative influence on the cells, since cultures stored in anaerobic conditions (under nitrogen) had a more prolonged survival' time. The cells which experienced between 10 and 60 days of starvation on the bench could be resuscitated, although the number of resuscitable cells depended strongly on the concentration of yeast extract in the resuscitation medium. This concentration for cells stored on the bench for more than 2 months was 0.05% while 1-month-old cells displayed a maximum resuscitability in the presence of 0.01% of yeast extract. Application of the fluorescent probe propidium iodide revealed the formation of cells with a damaged permeability barrier if resuscitation was performed by using concentrations of yeast extract of 0.1% and above. Thus the successful resuscitation of bacterial cultures under laboratory conditions may need rather strictly defined parameters if it is to be successfully performed for the majority of cells in a population.     

Phototrophic bacterial production of oleic acid in an illuminated upflow anaerobic sludge blanket reactor

Phototrophic bacterial cells in the effluent from a lighted upflow anaerobic sludge blanket reactor supplied with a medium containing 142 mg S (as SO₄ ^2–) l^–1 accumulated a 6.8% w/w oleic acid content in cells and 19 mg cell-bound oleic acid l^–1 in the effluent. Pure cultures of Rhodopseudomonas palustris and Blastochloris sulfoviridis isolated from the effluent also accumulated 5.1 and 6.4% w/w oleic acid contents in cells, respectively. The oleic acid content in the cells recovered from the LUASB reactor effluent was related to the phototrophic bacterial population in the LUASB reactor. The inverse relationship was observed in the LUASB reactor between phototrophic bacterial growth and sulfate concentration in the influent.     

A repeated batch process for cultivation of <Emphasis Type="Italic">Bifidobacterium longum</Emphasis>

A repeated batch process was performed to culture Bifidobacterium longum CCRC 14634. An on-line device, oxidation-reduction potential (ORP), was used to monitor cell growth and uptake of nutrients in the culture. The ORP of the culture medium decreased substantially during fermentation until nutrients were depleted. Six cycles of batch fermentation using ORP as a control parameter were successfully carried out. As soon as ORP remained constant or increased, three-quarters of the broth was removed, and the same volume of fresh medium was fed to the fermenter for a new cycle of cultivation. Average cell concentrations of 1.9×10⁹ and 3.4×10⁹ cfu ml^–1 for repeated batch fermentation in MRS (Lactobacilli MRS broth) and WY (containing whey hydrolyzates, yeast extract, l-cysteine) medium, respectively, were achieved. Cell mass productivities for batch, fed-batch and repeated batch fermentation using MRS medium were 0.51, 0.41, and 0.64 g l^–1 h^–1, respectively, and those for batch and repeated batch using WY medium were 0.76, 0.99 g l^–1 h^–1, respectively. The results indicate a possible industrial process to culture Bifidobacteria sp.     

A comparison of solid and liquid media for resuscitation of starvation- and low-temperature-induced nonculturable cells of Aeromonas hydrophila

Like many other gram-negative bacteria, starved cells of Aeromonas hydrophila can be induced into a viable but nonculturable (VBNC) state by incubation at low temperature, as shown here by using various bacterial enumeration methods. Starved A. hydrophila strain HR7 cells at 4 degrees C reached the nonculturable stage in about 45 days. The cells were resuscitated by either a solid medium resuscitation method, using solid agar amended with H2O2-degrading agents, catalase or sodium pyruvate, or a liquid medium resuscitation method, by incubating nonculturable cells in liquid media containing these compounds before spreading onto plates. The liquid medium resuscitation method using catalase resulted in nearly complete recovery of nonculturable cells.     

Effect of pH,aeration and sucrose feeding on the invertase activity of intactS. cerevisiae cells grown in sugarcane blackstrap molasses

S. cerevisiae was grown in a blackstrap molasses containing medium in batch and fed-batch cultures. The following parameters were varied: pH (from 4.0 to 6.5), dissolved oxygen (DO) (from 0 to 5.0 mg O₂L^–1) and sucrose feeding rate. When glucose concentration (S) was higher than 0.5 g L^–1 a reduction in the specific invertase activity of intact cells (v) and an oscillatory behavior of v values during fermentation were observed. Both the invertase reduction and the oscillatory behavior of v values could be related to the glucose inhibitory effect on invertase biosynthesis. The best culture conditions for attainingS. cerevisiae cells suitable for invertase production were: temperature=30°C; pH=5.0; DO=3.3 mg O₂L^–1; (S)=0.5 g L^–1 and sucrose added into the fermenter according to the equations: (V–V_o)=t²/16 or (V–V_o)=(V_f–V_o)·(e^0.6t–1)/10.This work was supported by FAPESP     

Optimisation of the cell release from immobilised cells of Bacillus simplex cultivated in culture media enriched with Cd2+: influence of Cd2+, inoculum size, culture medium and alginate beads characteristics

Calcium alginate beads were used to entrap a Bacillus sp. that has the ability to biosorb cadmium. During the batch incubation of alginate beads in a `rich' or a `poor' liquid medium, cell release out of the beads was noticed with a lag phase which was inversely proportional to the inoculum size (2×10⁷ or 2×10⁸ cells ml^–1 alginate), to the medium content, and proportional to the alginate concentration (10 or 15 g l^–1) and to the cadmium concentration (1, 5 or 10 mg l^–1). In addition, the cell release occurred more quickly when the medium was renewed. When the concentration was below 5 mg l^–1, the alginate matrix seemed to protect the bacteria against Cd²⁺ toxicity.     

Isolation and culture of protoplasts from callus tissue of Hibiscus syriacus L.

Protoplasts were isolated from callus tissue of Hibiscus syriacus L. using a solution of 3% Onozuka cellulase, 1% Onozuka macerozyme, and 0.5% hemicellulase. Highest yields of viable protoplasts were obtained from friable, white or yellow callus 8–9 days after subculture on Murashige & Skoog medium with 0.5 mg l^-1 2,4-dichlorophenoxyacetic acid and 0.1 mg l^-1 kinetin. Protoplasts cultured in thin liquid layers of this medium with mannitol continued dividing for longer than those cultured in droplets or in an agar medium. Cultures were maintained until protoplasts had divided to form groups of more than ten cells. Cell groups developed into callus and continued to grow on an agar medium, but failed to differentiate on a regeneration medium with 2 mg l^-1 naphthalene acetic acid and 1 mg l^-1 benzylaminopurine.     

In Vitro Long-Term Storage of Date Palm

A reliable method for the long-term conservation of date palm tissue cultures is described. In vitro shoot bud and callus culture were successfully stored for 12 months at 5°C in the dark. At this conditions high percent of cultures remained viable without serious signs of senescence. However, the growth rate decreased as storage period increased. The role of sorbitol as osmotic agent in storage was examined. Health shoot bud cultures were obtained after 6 months of storage on medium containing 40 g dm^–3 sorbitol. This period extended for 9 months in case of callus cultures.     

Synthesis of recombinant human interleukin-2 via controlled feed of lactose-complex media in fed-batch cultures of Escherichia coli BL21(DE3)[pT7-G3IL2]

Using lactose as an inducer, recombinant human interleukin-2 (rhIL-2) was synthesized with an N-terminus fusion partner, G3 (three tandem-arranged glucagon peptides) in fed-batch cultures at high cell concentration (60–90 g l^–1) of Escherichia coli BL21(DE3) [pT7-G3IL2]. With batch additions of lactose (4 × 13.5 g), the fusion rhIL-2 was synthesized up to 9.3 g l^–1. However, if all the lactose (54 g) was added at once to the culture, synthesized fusion rhIL-2 decreased to 5.4 g l^–1 with a decreased cell growth rate. A statistical optimization of the production medium containing glucose, yeast extract, and lactose led to fusion rhIL-2 being produced at > 9 g l^–1.