LE PLASTIDOME CHEZ EUGLENA GRACILIS Z1

Chloroplast morphology changes cyclically during each cell generation of synchronous photoheterotrophic cultures of Euglena gracilis Z; these cycles persist until the transition to stationary phase. Structural modifications, development of pyrenoids, and increase in chloroplast volume accompany the cessation of cell division. Chloroplasts of stationary phase heterotrophic cells resemble those of exponential phase autotrophic cells, suggesting a relationship between chloroplast morphology and available carbon.     

Photosynthetic Capacities and Growth Characteristics of Nicotiana tabacum (cv. Xanthi) Cell Suspension Cultures

Photoheterotrophic growth of cell suspensions of Nicotiana tabacum L. (cv. Xanthi) in organic culture medium enriched in sucrose (30 g per liter) showed a classical sigmoid growth curve. The cells developed functional chloroplast structures during the exponential growth phase, when their chlorophyll content increased steadily. A limited drop (30%) in the chlorophyll amount and structural changes of the plastids (starch accumulation) were observed during the lag phase. The measurements of photosynthetic capacities (O₂ evolution and CO₂ fixation) during the growth cycle revealed changes in the photosynthetic ratio (O₂/CO₂), which was near 1 during the lag and stationary phases and near 2 during exponential growth. During exponential growth there was also a rapid NO₃^? uptake. Analysis of label distribution among the products of ¹⁴CO₂ fixation showed that both CO₂ assimilation pathways, linked to the ribulose-biphosphate carboxylase (the autotrophic pathway) and to phosphoenolpyruvate carboxylase (the non-autotrophic pathway) were operative with an important increase of the capacity of the latter during the exponential growth phase. Maximum rate of oxygen evolution, either endogenous or with p-benzoquinone as Hill reagent, as well as the increased CO₂ Fixation capacity via the non-autotrophic pathway during the exponential phase were concomitant with a high cyanide inhibited O₂ uptake.     

Effects of nitrogen starvation on the photosynthetic physiology of a tropical marine microalga Rhodomonas sp. (Cryptophyceae)

The effects of nitrogen starvation on biomass composition and photosynthetic function were examined in the marine cryptophyte Rhodomonas sp. Batch-cultured cells in N-sufficient medium showed a 2.5-fold increase in total carbohydrate content, and a 33% increase in cell volume when the cultures reached the stationary growth phase. These cultures also increased the ratio of phycoerythrin (PE)/hydrosoluble proteins from 6 to 22% by the 4th and 10th day of culture, respectively. In contrast, light-saturated photosynthetic activity (P_m) progressively decreased, and the value obtained at the beginning of the stationary phase was about 45% of that obtained for cells in the late exponential growth phase. Transfer to N-lacking medium caused a 3.2-fold increase in cell volume. N starvation also triggered a rapid decline in N-containing compounds such as hydrosoluble proteins and photosynthetic pigments, causing an almost complete loss of PE. The ratio of PE/hydrosoluble proteins decreased from 6 to 1% after 6 d of N deprivation. Furthermore, the PSII fluorescence capacity declined under N-starved conditions, which caused a pronounced decrease in both the P_m (circa 90%) and the apparent photosynthetic efficiency (circa 55%). Under these conditions, photosynthetically fixed carbon was used to synthesize large amounts of carbohydrates. We suggest that, in addition to the role of phycoerythrin as a light-harvesting pigment, Rhodomonas sp. responds to N-depleted conditions by mobilizing combined nitrogen from biliproteins.     

Effect of plant growth regulators on the cellular growth and levels of intracellular protein,starch and polyamines in embryogenic suspension cultures of Pinus taeda

Somatic embryogenesis is the most important in vitro culture system for conifer propagation. However, Pinus taeda has been considered recalcitrant to somatic embryogenesis in commercial scale-up. The study of biochemical and physiological aspects of cell growth could lead to a better understanding of somatic embryogenesis in this species. In the present work, we investigated the cell growth dynamics, intracellular levels of proteins, starch and polyamines in suspension cultures of Pinus taeda established in plant growth regulator-free medium (BM0) and in medium supplemented with 2 M 2,4-dichlorophenoxyacetic acid, 0.5 M 6-benzylaminopurine and 0.5 M Kinetin (BM2). Cell cultures growing in BM0 medium showed an increase in the sedimented cell volume from 3.77 to 17.73 ml after 24 days of culture. Those cultured in BM2 medium showed an increase in the sedimented cell volume from 4.23 to 25.17 ml after 20 days of culture. Intracellular proteins levels increased during the exponential growth phase and starch levels decreased until the exponential phase, followed by a synthesis up to the stationary phase, in both BM0 and BM2 media. Highest putrescine levels occurred in cultures growing in BM0 medium and this was associated with the low cellular growth.     

SILICATE DEFICIENCY AND LIPID SYNTHESIS OF MARINE DIATOMS1,2

Lipid synthesis of three marine diatoms was studied with a ¹⁴CO₂ incorporation technique in silicate limited batch cultures. Growth rates were independent of the silicate concentration but the cellular yields were proportional to the initial amount of silicate. At the beginning of the stationary growth phase, lipid synthesis rates per unit culture volume increased by 1.7 times for Chaetoceros gracilis, 3.1 times for Hantzschia sp., and 2.8 times for Cyclotella sp., respectively compared to those during the exponential growth phase. Lipid carbon accounted for as much as 57% of the carbon in C. gracilis, 71% in Hantzschia sp., and 65% in Cyclotella sp., respectively. Additional enrichment with silicate during stationary growth phase allowed the cultures to grow further. Lipid synthesis rates were reduced during the subsequent growth phase, and the growth rates themselves were dependent on the level of biomass achieved during the previous stationary phase. However, the cellular yields were similar and probably controlled by light.     

Cell arrangement,mass and dimension ofStreptococcus faecalis during growth

During exponential growth ofStreptococcus faecalis, the distribution of cell arrangements remains constant, but depends on the growth rate. The predominant cell arrangements are diplococci (about 60–80% of total cells) the amount of which varies only little with the growth rate. A clear correlation exists for cells growing as chains; the amount decreases from about 20% at μ=2.0 to about 6% at μ=0.45. After cessation of growth in the stationary phase, the number of diplococci and chains decreases and the number of monococci increases; after 10 h in the stationary phase, more than 50% of the cells have become monococci. The dry weight of 2.5×10⁻¹⁰ mg/cell remains constant at different growth rates, while cell size shows small differences on different growth media. Treatment of exponentially growing cultures with crystal violet or nitrofurantoin results in faster sedimentation on sucrose gradients of treated cultures compared to untreated cultures. While crystal violet effects an increased chain formation, treatment with nitrofurantoin results in an increase of the size of the individual cell.     

Effect of age on the membrane lipid composition of Streptococcus sanguis

The cell membrane of Streptococcus sanguis contains three classes of lipid: neutral lipid, glycolipid and phospholipid. A striking difference in membrane lipid composition between cells in the exponential and in the stationary phases of growth was observed. During the exponential phase, approx. 37–45%, 14–19% and 37–45% of the lipids synthesized were found to be neutral lipid, glycolipid and phospholipid, respectively. The amount of lipid synthesized reached a maximum at the early stationary phase. The amount of phospholipid drastically declined thereafter and that of neutral lipid slightly declined. In contrast, the amount of glycolipid markedly increased and exceeded the amount of phospholipid. The phospholipid present during the exponential phase was found to be mainly phosphatidylglycerol (82–88%) and a small amount of cardiolipin (12–18%). At the stationary phase, the amount of phosphatidylglycerol greatly decreased and reached approx. 16% of that in the early stationary phase, while cardiolipin steadily increased and became the major phospholipid in the late stationary phase. The glycolipid was found to be composed of mainly mono- and diglucosyldiglycerides. At the end of the experiment (after 8 h incubation), the distribution of lipids was found to be: neutral lipid, 46%; glycolipid (monoglucosyldiglyceride, 28%; diglucosyldiglyceride, 13%) 41%; and phospholipid (phosphatidylglycerol, 3%, cardiolipin, 8%) 13%.     

Effect of growth temperature and media composition on the fatty acid composition of Bacillus stearothermophilus AN 002

The influence of growth temperature, media composition and cell age on the chemical composition of Bacillus stearothermophilus strain AN 002 has been determined. The total cellular protein decreased and the free amino acid content increased with growth temperature, in both exponential and stationary growth phase. The protein and free amino acid contents of cells were higher in the stationary phase than in the exponential phase, irrespective of growth temperature and media composition. The RNA content was only reduced in cells grown at 55° C. No significant variations were observed in the DNA and carbohydrate contents with respect to growth temperature and cell age. The total lipid and fatty acid compositions on the other hand varied as a function of growth temperature, cell age and media composition. Differences in the relative concentrations of even, odd and branched chain fatty acids were noticed. Novariation was observed in the antiiso and unsaturated fatty acids with respect to growth temperature. The unique variations in the fatty acid composition and total lipids at the growth temperature of 50° C and their variations in the stationary growth phase seem to be characteristic for B. stearothermophilus AN 002.     

Growth characteristics of hormone and vitamin independent photoautotrophic cell suspension cultures fromChenopodium rubrum

Summary This communication reports the photoautotrophic growth of hormone and vitamin independent cell suspension cultures ofChenopodium rubrum. The transfer of cells from stationary growth into fresh culture medium results in a high protein formation, followed by an exponential phase of cell division, whereas the onset of rapid chlorophyll formation is delayed for 4 days. At the stage of most rapid cell division there is no net synthesis of starch and sugar. When the cells enter stationary growth, there is a progressive accumulation of chlorophyll, sugar, and starch.Photoautotrophic cell cultures assimilate about 80–90 mol CO₂/mg chlorophyll X hour. Dark CO₂ fixation is about 3.7% to 2.2% of the light values during exponential and stationary growth, respectively. As shown by short-term¹⁴CO₂ fixation, CO₂ is predominantly assimilated through ribulosebisphosphate carboxylase via the Calvin pathway. There is a significant increase in the¹⁴C label of C₄ carboxylic acids in exponentially dividing cells as compared to cells from stationary growth. Thein vitro activity of phosphoenolpyruvate carboxylase and ribulosebisphosphate carboxylase is almost equal during exponential cell division. A decrease in cell division activity is accompanied by a significant change in the specific activities of both carboxylation enzymes. In non dividing cells from stationary growth the activity of ribulosebisphosphate carboxylase is greately enhanced and that of phosphoenolpyruvate carboxylase is reduced, documenting the development of carboxylation capacities typical for C₃-plants.The experimental results provide evidence that phosphoenolpyruvate carboxylase activity might be regulated by ammonia and could be involved in anaplerotic CO₂ fixation which supplies carbon skeletons of the citric acid cycle.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - EDTA ethylene-diamine-tetraacetic acid - FDP fructose bisphosphate - F-6-P fructose-6-phosphate - G-6-P glucose-6-phosphate - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - PGA 3-phosphoglyceric acid - PEP phosphoenolpyruvate - RuDP ribulosebisphosphate     

Extracting information on the evolution of living- and dead-cell fractions of Salmonella Typhimurium colonies in gelatin gels based on microscopic images and plate-count data

Aims:  The aim of this study was to extract information on cell number and colony volume dynamics of Salmonella Typhimurium colonies.
Methods and Results:  Both cell number and colony volume of Salmonella Typhimurium in gelatin were monitored during the exponential and the stationary phase with varying pH and water activity, by plate counts and microscopic image analysis respectively. The exponential growth rates of cell numbers and colony volumes were correlated. The exponential growth rate of cell numbers was estimated based on this correlation and a secondary model that describes the effect of pH and water activity on the growth rate of the colony volumes. During the stationary phase, the cell number was constant, while colony volume increased, thus indicating the formation of a dead fraction. Models were developed to describe the living and dead population.
Conclusions:  By comparing colony volumes and cell numbers, the formation of dead fraction can be noticed from the beginning of the stationary phase, which indicates that the stationary phase is a dynamic – including both cell death and cell growth – rather than a static phase.
Significance and Impact of the Study:  This study was the first to investigate the proportion of living and dead bacteria within a stationary colony quantitatively.     

The effect of temperature on the growth and lipid composition of the extremely halophilic coccus,Sarcina marina

Sarcina marina (NCMB 778) grew over the temperature range 20–45°C but no growth was recorded at 15°C or 50°C. At the optimum growth temperature of 34°C the doubling time was 14.5 h.The major polar lipid components, tentatively identified as the diether analogues of phosphatidyl glycerophosphate (PGP), phosphatidyl glycerol (PG), diglycosyl diglyceride (DGD) and triglycosyl diglyceride (TGD), and the major neutral lipid components, tentatively identified as squalene, dihydrosqualene, tetrahydrosqualene, vitamin MK8, geranyl geraniol and di-O-phytanyl glycerol, are identical to those found in other extremely halophilic rods and cocci.The total lipid content varied with growth conditions from 0.6 – 3.2% of the dry cell weight, polar lipids accounted for between 94.3 and 83.6% of the total lipid, the remainder being neutral lipid.In response to both the transition from exponential to stationary phase and a reduction of 14°C in growth temperature, batch cultures showed: (i) an increase in total lipid content; (ii) a decrease in PG and (iii) an increase in PGP. Specific responses to the temperature decrease were (i) increased total lipid content; (ii) no decrease in neutral lipids in stationary phase; (iii) marked reduction in PG and (iv) raised DGD. (i) and (ii) could be mechanisms for increasing membrane fluidity.In common with all other extreme halophiles investigated the alkyl side chains of S. marina polar lipids were identified as the phytanyl (3R, 7R, 11R, 15-tetramethylhexadecyl) group. Its structure did not appear to vary with temperature so that the normal mechanisms for modifying the structure of lipid alkyl side chains to modulate membrane fluidity in response to temperature changes probably does not occur in this group of microorganisms.     

Growth Stimulating Substance for Microorganisms Produced by Escherichia coli Causing the Reduction of the Lag Phase in Microbial Growth and Identity of the Substance with Pyrroloquinoline Quinone

The finding that most strains of microbes produce a growth stimulating substance for microorganisms was demonstrated and confirmed with the culture broth of Escherichia coli grown on a glucose-mineral medium. Addition of culture broth of E. coli to the culture media of the others markedly reduced the lag phase in microbial growth but not growth rate in the subsequent exponential phase nor the total cell yield in the stationary phase. The growth stimulation causing reduction of the lag phase was dependent on the amount of culture broth added. Occurrence of cell growth was essential for the excretion of the growth stimulating substance by E. coli. Under identical inoculum size, even with a heavy inoculum, a further reduction of the lag phase was observed by the addition of culture broth of E. coli. The substance was only effective at the initial growth phase but inert when the substance was added to a growing culture at the exponential phase. Finally, the substance was identified as pyrroloquinoline quinone, a newly established coenzyme, through chromatographic, spectroscopic and enzymatic criteria.     

Control of macromolecular synthesis in proliferating and resting Syrian hamster cells in monolayer culture. I. Ribosome function

The rate of protein synthesis per cell in cultured hamster embryo fibroblasts in the stationary growth phase falls to about one third of the rate in the exponential growth phase. This reduction can be entirely accounted for by the following observations: (1) the average cell in stationary phase contains about one-half the number of ribosomes per cell compared to the average cell in exponential phase; (2) only two thirds of the ribosomes are bound to polysomes in stationary phase, while nearly all of the ribosomes are polysome-bound in exponential phase. In stationary phase, ribosomes which are polysome-bound function with the same efficiency and produce proteins of approximately the same average length as in exponential phase. Experimental findings are presented which suggest that the generation of a higher proportion of free ribosomes in stationary phase in not due to a limitation in messenger RNA, but to a decreased attachment probability of ribosomes to messenger RNA.     

Linear growth and lipid synthesis in the oleaginous yeastRhodotorula gracilis

A kinetic analysis was made of batch cultures of an industrially important yeastRhodotorula gracilis, using a nitrogen-limited medium. The exponential phase of growth lasted 15 h, followed by a linear phase up to 36 h. The generation time was 2.8 h (15–36 h of fermentation) which corresponded to a μ of 0.248/h. The lipid synthesis was partially growth-associated with the linear growth phase (15–36 h) and the early stationary phase (36–60 h). The rate of linear growth was estimated as 0.267 g cell per L per h and the rate for lipid synthesis over the period of 15–60 h was 0.17 g lipid per L per h. More than 50% of the total supplied nitrogen was assimilated by the organism and the rest remained in the medium. Sugar assimilation was nearly 100% by the end of 60-h fermentation. At 0 h the intracellular protein was 3.3% and it significantly increased to 11.7% by the end of 12 h. Morphological and physiological characteristics were also found to change during different stages of growth.     

GROWTH AND DOMOIC ACID PRODUCTION BY PSEUDO‐NITZSCHIA SERIATA (BACILLARIOPHYCEAE) UNDER PHOSPHATE AND SILICATE LIMITATION1

Pseudo‐nitzschia seriata (Cleve) H. Peragallo isolated from Scottish west coast waters was studied in batch culture with phosphate (P) or silicate (Si) as the yield‐limiting nutrient at 15°C. This species produced the neurotoxin domoic acid (DA) when either nutrient was limiting but produced more when stressed by Si limitation during the stationary phase. Under P‐limiting conditions, exponential growth stopped after P was reduced to a low threshold concentration. Under Si‐limiting conditions, fast exponential growth was followed by a period of slower exponential growth, until Si became exhausted. A stationary phase was observed in the P‐limited but not the Si‐limited cultures, the latter showing a rapid decrease in cell density after the second exponential growth phase. Si‐limited cultures exhibited a further period of active metabolism (as indicated by increases in chl and carbon per cell) late in the experiment, presumably fueled by regenerated Si. DA production was low in exponential phase under both conditions. In P‐limited cultures, most DA was produced during the immediate postexponential phase, with little or no new DA produced during later cell senescence. In contrast, although a substantial amount of DA was produced during the slower exponential phase of the Si‐limited cultures, DA production was even greater near the end of the experiment, coincident with the period of chl synthesis and increase in carbon biomass. Comparison of the magnitude of toxin production in the two nutrient regimes indicated a greater threat of P. seriata‐generated amnesic shellfish poisoning events under Si rather than P nutrient limitation.     

Regulation of RNA polymerase sigma subunit synthesis in Escherichia coli: intracellular levels of sigma 70 and sigma 38.

The intracellular levels of two principal sigma subunits, sigma 70 (sigma D, the rpoD gene product) and sigma 38 (sigma s, the rpoS gene product), in Escherichia coli MC4100 were determined by a quantitative Western immunoblot analysis. Results indicate that the level of sigma 70 is maintained at 50 to 80 fmol per micrograms of total proteins throughout the transition from the exponential growth phase to the stationary phase, while the level of sigma 38 protein is below the detection level at the exponential growth phase but increases to 30% of the level of sigma 70 when cell growth stops to enter into the stationary phase. Beside the stationary phase, the increase in sigma 38 level was observed in two cases: exposure to heat shock at the exponential phase and osmotic shock at the stationary phase.     

Lipids of Cunninghamella echinulata with emphasis to γ-linolenic acid distribution among lipid classes

Changes in lipid composition of the oleaginous fungus Cunninghamella echinulata were monitored during growth. Lipid fractions and individual lipid classes varied in amount, relative proportions, and fatty acid profile depending on the developmental stage. Neutral lipids (N), comprised mainly of triacylglycerol, were accumulated in the fungal mycelium during both the late exponential and the stationary growth phases with a concomitant decrease in the amount of polar lipids. While fatty acid composition of N fraction remained almost constant, individual N classes showed a noticeable alteration in γ-linolenic acid (GLA) concentration. The glycolipid plus sphingolipid (G+S) fraction consisted mainly of monoglycosylglycerol and diglycosylglycerol. The sugar composition of G+S fraction was analyzed and showed a partial replacement of galactose for glucose as growth proceeded. Phospholipid (P) major classes were phosphatidylcholine (PC) and phosphatidylethanolamine, followed by phosphatidylinositol, phosphatidylserine, and diphosphatidylglycerol. P fatty acid composition showed significant changes with time, resulting in a considerable drop in the unsaturation index of this fraction. While in mid exponential growth phase, all P classes contained more than 20% w/w GLA of total fatty acids, and their concentration decreased to 12–17% w/w, except for the PC class where GLA concentration remained at high levels (e.g., more than 20% w/w). The constant level of GLA in PC at all growth phases suggests that PC was the major source of GLA. Sterol analysis showed that their concentration increased during growth, whereas ergosterol was the major component.     

Analysis of rRNA gene content in the Mediterranean dinoflagellate <Emphasis Type="Italic">Alexandrium catenella</Emphasis> and <Emphasis Type="Italic">Alexandrium taylori</Emphasis>: implications for the quantitative real-time PCR-based monitoring methods

A number of species belonging to the genus Alexandrium are among the main toxic microalgae responsible for Harmful Algal Blooms (HABs). The monitoring of coastal waters for the presence of these microalgae is essential to identify correlations between cell abundances and environmental factors that regulate bloom dynamics. In the attempt to improve the monitoring sensitivity and the rapidity at which a large number of field samples can be processed, several molecular methods for the detection of genetically distinct HAB species have been developed during the last years. In particular, real-time PCR has been shown to be a powerful method for quantitative detection of HAB species in environmental samples. When a plasmid is used as a standard, the knowledge of the amount of target gene per cell is essential for the determination of the cell number in the field sample. In this study, we analyzed the rRNA gene content variability in several Alexandrium catenella and Alexandrium taylori strains isolated from the Mediterranean Sea using a real-time PCR-based approach. The rRNA gene content was also analyzed in different growth phases, from early exponential to stationary conditions. The results showed a general variability in the rRNA gene content depending on the strain and, for the species A. taylori, in relation also to the growth phase. These results should be taken into account for the application of the real-time quantitative PCR-based techniques for monitoring purposes in coastal seawaters.     

Relation between the damaging effect of surface-active compounds on Escherichia coli cells and the phase of culture growth

The techniques of cell electrophoresis and electro-orientation spectroscopy were used to study the effect of sodium dodecyl sulfate (SDS) and cetyl trimethyl ammonium bromide (CTAB) on Escherichia coli K-12 cells from the culture at the exponential and stationary growth phases. SDS (2 x 10(-4) M) considerably damaged cells at the exponential phase, particularly at pH less than 6.0, whereas cells at the stationary phase were damaged to a less degree and only at pH less than 5.3 or after their treatment with Trilon B. The damaging effect of SDS decreased in an isotonic medium (0.25 M sucrose) as compared to a hypotonic medium (distilled water). CTAB also damaged cells at the exponential phase more than those at the stationary phase, and its damaging action decreased with pH. Mg2+, Ca2+, and Sr2+ cations diminished the degree of cell damage with CTAB, but did not exert any noticeable protection in the case of SDS. The different sensitivity of cells at the exponential and stationary growth phases may be associated with changes in their surface electric charge and with the existence of hydrophobic regions on the cell surface. The higher electric charge of cells at the stationary growth phase is presumed to stem from a rise in the amount of surface lipopolysaccharides which bear a negative electric charge.     

DETECTION OF THE TOXIC DINOFLAGELLATE ALEXANDRIUM FUNDYENSE (DINOPHYCEAE) WITH OLIGONUCLEOTIDE AND ANTIBODY PROBES: VARIABILITY IN LABELING INTENSITY WITH PHYSIOLOGICAL CONDITION

The toxic dinoflagellate Alexandrium fundyense Balech was grown under temperature- and nutrient-limited conditions, and changes in labeling intensity on intact cells were determined for two probe types: an oligonucleotide probe targeting rRNA and a monoclonal antibody (MAb) targeting a cell surface protein. In nutrient-replete batch culture, labeling with the rRNA probe was up to 400% brighter during exponential phase than during stationary phase, whereas MAb labeling did not change significantly with growth stage at the optimal growth temperature. In cultures grown at suboptimal, low temperatures, there was a significant difference between labeling intensity in stationary versus exponential phase for both probe types, with exponential cells labeling brighter with the rRNA probe and slightly weaker with the MAb. The decrease in rRNA probe labeling with increasing culture age was likely due to lower abundance of the target nucleic acid, as extracted RNA varied in a similar manner. With the MAb and the rRNA probes, slower growing cultures at low, nonoptimal temperature labeled 35% and 50% brighter than cells growing faster at warmer temperatures. Some differences in labeling intensity per cell disappeared when the data were normalized to surface area or volume, which indicated that the number of target antigens or rRNA molecules was relatively constant per unit area or volume, respectively. Slow growth accompanying phosphorus and nitrogen limitation resulted in up to a 400% decrease in labeling intensity with the rRNA probe compared to nutrient-replete levels, whereas the MAb labeling intensity increased by a maximum of 60%. With both probes, labeling was more intense under phosphorus limitation than under nitrogen limitation, and for all conditions tested, labeling intensity was from 600% to 3600% brighter with the MAb than with the rRNA probe. Thus, it is clear that significant levels of variability in labeling intensity can be expected with both probe types because of the influence of environmental conditions and growth stage on cellular biochemistry, cell size,rRNA levels, and the number or accessibility of cell surface proteins. Of the two probes tested, the rRNA probe was the most variable, suggesting that in automated, whole-cell assays, it can be used only in a semiquantitative manner. For manual counts, the human eye will likely accommodate the labeling differences. The MAb probe was less variable, and thus should be amenable to both manual and automated counts.