Starvation-Survival Patterns of Sixteen Freshly Isolated Open-Ocean Bacteria

Sixteen marine isolates from a NORPAX cruise, which were transferred once on medium after initial isolation, survived nutrient deprivation for at least 8 months (longest period test). All but one isolate remained cellularly intact, although their sizes and shapes changed greatly, and all became smaller, decreasing in size from 40 to 79%. Three starvation-survival patterns were demonstrated, namely (i) an initial increase in viable cells followed by a decrease until a constant number was reached, (ii) an increase in viable cells until a constant number was reached, and (iii) a decrease in viable cells until a constant number was reached. One isolate from each starvation-survival pattern was starved for 8 months and then was tested in comparison with 4-month-starved Ant-300 for [¹⁴C]glutamic acid uptake, respiration, and incorporation. The response to glutamic acid was rapid and linear in each case. The data indicate that the starvation-survival of Ant-300 is not an anomalous situation and that open ocean bacteria can withstand nutrient deprivation for long periods of time and still retain the capacity for active metabolism, if the nutrients become available.     

Survival of a Psychrophilic Marine Vibrio Under Long-Term Nutrient Starvation

Ant-300, a psychrophilic marine vibrio isolated from the surface water of the Antarctic convergence, was starved for periods of more than 1 year. During the first week of starvation, cell numbers increased from 100 to 800% of the initial number of cells. Fifty percent of the starved cells remained viable for 6 to 7 weeks while a portion of the population remained viable for more than 1 year. During the first 2 days of starvation, the endogenous respiration of the cells decreased over 80%. After 7 days, respiration had been reduced to 0.0071% total carbon respired per hour and remained constant thereafter. After 6 weeks of starvation, 46% of the cellular deoxyribonucleic acid had been degraded. Observation of the cellular deoxyribonucleic acid with Feulgen staining before starvation showed the average number of nuclear bodies per cell varied from 1.44 to 4.02 depending on the age of the culture. A linear relationship was found between the number of nuclear bodies per cell and the increase in cell numbers upon starvation. Our data suggest that Ant-300 is capable of surviving long periods of time with little or no nutrients and is therefore well adapted for the sparse nutrient conditions of the colder portions of the open ocean.     

Protein Patterns of Growing and Starved Cells of a Marine Vibrio sp

Fingerprint protein patterns were produced by two-dimensional polyacrylamide electrophoresis on lysed cells of a Vibrio sp., Ant-300, which were prepared from growing and starved cultures. The cells were labeled with [S]methionine during growth and subsequently starved for up to 30 days. Samples were taken at selected time points representing stages in the starvation-survival process. Unlabeled starved cells were allowed to recover in the presence of [S]methionine to determine protein changes associated with the recovery from starvation. All growth conditions produced similar protein fingerprints; however, some protein spots disappeared, whereas others were seen only during starvation.     

Protein Patterns of Growing and Starved Cells of a Marine Vibrio sp.

Fingerprint protein patterns were produced by two-dimensional polyacrylamide electrophoresis on lysed cells of a Vibrio sp., Ant-300, which were prepared from growing and starved cultures. The cells were labeled with [³⁵S]methionine during growth and subsequently starved for up to 30 days. Samples were taken at selected time points representing stages in the starvation-survival process. Unlabeled starved cells were allowed to recover in the presence of [³⁵S]methionine to determine protein changes associated with the recovery from starvation. All growth conditions produced similar protein fingerprints; however, some protein spots disappeared, whereas others were seen only during starvation.     

Effect of Growth Rate and Starvation-Survival on Cellular DNA, RNA, and Protein of a Psychrophilic Marine Bacterium

DNA, RNA, and protein concentrations from starved ANT-300 cell populations grown at different growth rates fluctuated corresponding to the three stages of starvation-survival on total and viable cell bases. During stage 1 of starvation-survival, two to three peaks in the concentration levels for all three macromolecules were characteristic. During stage 2, DNA per total cell dropped to between 4.2 and 8.3% of the original amount for all of the cell populations examined, and it stabilized throughout stage 3. The decrease in DNA per cell was also observed in electron micrographs of cellular DNA in unstarved compared with starved cells. The fluctuations of RNA and protein per total cell concentrations observed during stage 2 coincided in all cases, except for the cells from dilution rate (D) = 0.015 h⁻¹. This ANT-300 cell population showed a decrease in RNA per total cell to only 29.2% and an increase in protein to 129.7% of the original amount after 98 days of starvation. During stage 3, DNA, RNA, and protein concentrations per total cell also stabilized to continuous levels. Cells from the faster-growth-rate cell populations of D = 0.170 h⁻¹ and batch culture had elevated protein per total cell concentrations, which remained primarily residual during the starvation period. Starved cells from D = 0.015 h⁻¹ had estimated nucleoid and cell volumes of 0.018 and 0.05 μm³, respectively, yielding a nucleoid volume/cell volume ratio of 0.40. We consider these data to indicate that slow-growth-rate cells are better adapted for starvation-survival than their faster-growth-rate counterparts.     

Adenosine triphosphate pool levels and endogenous metabolism in Arthrobacter crystallopoietes during growth and starvation

The adenosine triphosphate (ATP) content of Arthrobactery crystallopoietes was measured during growth, starvation and recovery from starvation. During exponential growth of the cells as spheres in a glucose salts medium, the level of ATP per cell remained constant at 8.0×10^-10 g/cell. Morphogenesis to rodshaped cells and an increased growth rate following addition of casein hydrolysate was accompanied by an almost two-fold increase in the ATP level. As division of the rod-shaped cells proceeded, the level of ATP declined. After growing as rods for 12–14 h the cells underwent fragmentation to spheres during which time the ATP level again increased to the original value of 8.0×10^-10 g/cell. As the spherical cells resumed growth on the residual glucose, their ATP content declined for a short period and then remained relatively constant. During starvation of sphere or rod-shaped cells for one week, the ATP level declined by approximately 70% during the first 40–50 h and then remained constant. The endogenous metabolism rate of spherical cells declined during the first 10–20 h of starvation and then remained constant at approximately 0.02% of the cell carbon being utilized per h. Addition of glucose to spherical cells which had been starved for one week increased both the ATP content per cell and their rate of endogenous metabolism. The ATP content fluctuated and then remained at a level higher than maintained during starvation while endogenous metabolism quickly declined.Non-Standard Abbreviations ATP adenosine triphosphate - GS glucose mineral salts - HC casein hydrolysate - PVP polyvinylpyrrolidone - DMSO dimethylsulfoxide - MOPS morpholinopropane sulfonic acid - EDTA ethylene diaminetetraacetic acid     

Starvation Response of the Marine Barophile CNPT-3

The psychrophilic marine barophile CNPT-3 underwent a starvation-survival response similar to that reported for the marine bacteria Ant-300, DW1, and S-14. The number of culturable cells increased initially and then decreased gradually over a 24-day starvation period, with corresponding decreases in total cell number and direct viability count. A significant reduction in cell size and biovolume accompanied these changes. Starved cells demonstrated a greater tendency to attach at the in situ pressure (400 atm; ca. 40.5 MPa) and temperature (5°C) than at 1 atm (ca. 101 kPa), and the extent of attachment increased with increasing duration of starvation. The membrane fatty acid profile of the marine barophile CNPT-3 was studied as the cells were subjected to starvation conditions. A 37.5% increase in saturated fatty acids was observed during the first 8 days of starvation, with a concomitant decrease in unsaturated fatty acids. There was also an increase in the amount of short-chain (<C_15:0) fatty acids.     

Recovery from nutrient starvation by a marine Vibrio sp

A marine psychrophilic Vibrio sp., Ant-300, recovered from starvation after the addition of 1 volume of complete nutrient medium to 9 volumes of starvation menstruum. Turbidity (measured by optical density), viable cell counts, cell size (measured from electron micrographs), and cellular concentrations of protein, DNA, and RNA were monitored with recovery time. The usual growth curve of bacterial cultures was observed. On a per viable cell basis, protein, DNA, and RNA increased to maximum values just before cell division and then returned to close to the initial starved-cell value during the stationary phase. Cells under complete starvation conditions or missing only one nutrient in the stationary phase responded with cell division resulting in many smaller cells. The length of the lag phase during recovery was directly proportional to the length of the prior starvation period, even when identical numbers of cells were used for recovery. Cells appeared to pass more deeply into dormancy with starvation time.     

Recovery from nutrient starvation by a marine Vibrio sp.

A marine psychrophilic Vibrio sp., Ant-300, recovered from starvation after the addition of 1 volume of complete nutrient medium to 9 volumes of starvation menstruum. Turbidity (measured by optical density), viable cell counts, cell size (measured from electron micrographs), and cellular concentrations of protein, DNA, and RNA were monitored with recovery time. The usual growth curve of bacterial cultures was observed. On a per viable cell basis, protein, DNA, and RNA increased to maximum values just before cell division and then returned to close to the initial starved-cell value during the stationary phase. Cells under complete starvation conditions or missing only one nutrient in the stationary phase responded with cell division resulting in many smaller cells. The length of the lag phase during recovery was directly proportional to the length of the prior starvation period, even when identical numbers of cells were used for recovery. Cells appeared to pass more deeply into dormancy with starvation time.     

Energy metabolism of Bdellovibrio bacteriovorus

Bdellovibrio bacteriovorus, strain Bd. 109 Sa, generates ATP mainly by oxidative phosphorylation during electron transport. During exponential growth the ATP pool is constant (9 nmoles/100 μg N) indicating that energy-producing and energy-consuming reactions are well balanced. The ratio of substrate respiration/endogenous respiration is approx. 2.5/1. Energy charge is constant both in endogenous and substrate respiration at values of 0.62 to 0.64. During endogenous respiration (starvation) the ATP pool oscillates at regular intervals. ATP over-production is started after the ATP pool has decreased to a minimum level of 6 nmoles/100 μg N. The alternating over- and under-production of ATP is interpreted as a special regulation which enables the organism to make economic use of its own cellular materials. Addition of substrate (glutamate) to starving cells does not influence the type of ATP pool oscillation as observed in endogenous respiration. The parasitic strain Bd. 109 Pa exhibits the same periodicity of ATP overproduction as does its saprophytic derivative, Bd. 109 Sa. Decrease of viability during starvation is paralleled by a decrease of the ATP pool.     

Energy metabolism of Bdellovibrio bacteriovorus. I. Energy production, ATP pool, energy charge.

Bdellovibrio bacteriovorus, strain Bd. 109 Sa, generates ATP mainly by oxidative phosphorylation during electron transport. During exponential growth the ATP pool is constant (9 mmoles/100 mugN) indicating that energy-producing and energy-consuming reactions are well balanced. The ratio of substrate respiration/endogenous respiration is approx. 2.5/1. Energy charge is constant both in endogenous and substrate respiration at values of 0.62 to 0.64. During endogenous respiration (starvation) the ATP pool oscillates at regular intervals. ATP over-production is started after the ATP pool has decreased to a minimum level of 6 nmoles/100 mug N. The alternating over- and under-production of ATP is interpreted as a special regulation which enables the organism to make economic use of its own cellular materials. Addition of substrate (glutamate) to starving cells does not influence the type of ATP pool oscillation as observed in endogenous respiration. The parasitic strain Bd. 109 Pa exhibits the same periodicity of ATP overproduction as does it saprophytic derivative, Bd. 109 Sa. Decrease of viability during starvation is paralleled by a decrease of the ATP pool.     

Study of β-III tubulin expression in human eye tissues during prenatal development

The expression of β-III tubulin, a marker protein of early neuronal cells, was studied by molecular genetic and immunochemical techniques. The study was performed with the eyes of human fetuses on weeks 8.5 to 27–28 of intrauterine development. Expression of β-III tubulin was detected immunochemically in the retina and lens fibers of fetuses at stages of 8.5 to 22–23 weeks. By means of PCR, a strong expression of the β-III tubulin gene was revealed in the retina of 9.5-week fetuses. Its level remained high until week 18, became slightly lower by week 24, and decreased to zero by week 27–28. The expression of this gene was also revealed in the lens of 9.5-week fetuses. Its level at stages of 15 to 24 weeks was very low, and no expression could be detected in 27-to 28-week fetuses. The results of PCR analysis were consistent with immunochemical data.     

Morphological characterization of small cells resulting from nutrient starvation of a psychrophilic marine vibrio.

Upon starvation, Ant-300, a psychrophilic marine vibrio, was observed to decrease in size and change in shape from a rod to a coccus. After 3 weeks of starvation 50% of the starved population was able to pass through a filter with a pore size of 0.4 mum. Electron microscopy of thin sections of the small cells revealed normal cell structure except for an enlarged periplasmic space. When inoculated into a fresh medium, starved cells growth without a significant lag and regained "normal" size and shape within 48 h.     

Toxicity of toluene and o-xylene toAcinetobacter calcoaceticus in starvation-survival mode

Summary Toxicity of toluene and o-xylene was tested with a deep subsurface isolate during 120 day starvation period. During 120 day starvation period, toxicity appeared to increase with cell age until cells reached the starvation mode. This result may have an significant implication toin situ bioremediation applications since subsurface bacterial populations are apparently in starvation-survival mode.     

Characterization of the Starvation-Survival Response of Staphylococcus aureus

The starvation-survival response of Staphylococcus aureus as a result of glucose, amino acid, phosphate, or multiple-nutrient limitation was investigated. Glucose and multiple-nutrient limitation resulted in the loss of viability of about 99 to 99.9% of the population within 2 days. The remaining surviving cells developed increased survival potential, remaining viable for months. Amino acid or phosphate limitation did not lead to the development of a stable starvation-survival state, and cells became nonculturable within 7 days. For multiple-nutrient limitation, the development of the starvation-survival state was cell density dependent. Starvation survival was associated with a decrease in cell size and increase in resistance to acid shock and oxidative stress. There was no evidence for the formation of a viable but nonculturable state during starvation as demonstrated by flow cytometry. Long-term survival of cells was dependent on cell wall and protein biosynthesis. Analysis of [³⁵S]methionine incorporation and labelled proteins demonstrated that differential protein synthesis occurred deep into starvation.     

Change in energy metabolism of ascites cancer cells with a decrease in pH]

In Hank's balanced salt solution EL-4 ascites thymoma cells possessed endogenous respiration which was sufficient for the maintenance of their ATP level: pH decrease down to 6.0 had no effect either on endogenous respiration or the ATP level. Glucose had no influence on the respiration of EL-4 cells but inhibited that of Ehrlich ascites carcinoma (EAC) cells by 40% (Crabtree effect); respiration of the both cell lines was strongly (4-fold) inhibited after simultaneous addition of glucose, lactate and pH decrease. EL-4 cells had no endogenous glycolysis; EAC cells showed a low level of glycolysis only after pH decrease. Glucose addition led to activation of glycolysis (both inhibited 2-fold after a decrease of pH down to 6.0. The respiration inhibition at pH 7.3 and 6.0 caused no decrease of ATP depletion when glucose was present in the medium; this result may be due to suppression of ATP consumption. Incubation of EL-4 cells under respiration and glycolysis deficiency conditions resulted in a sharp ATP depletion; pH decrease delayed this depletion.     

The effect of feed cycling and ration level on the compensatory growth response in rainbow trout, Oncorhynchus my kiss

Compensatory growth is the phase of rapid growth, greater than normal or control growth, which occurs upon adequate refeeding following a period of undernutrition. The effect of feed cycling periods (periods of starvation followed by periods of refeeding), ration level and repetitive feed cycles on the compensatory growth response in rainbow trout were evaluated in two experiments. A feeding cycle of 3 weeks starvation and 3 weeks feeding produced better results in terms of average percentage changes in weight and length, and in specific growth rate, than either 1 week and 1 week or 2 weeks and 2 weeks feed cycles. The fish on the 3 weeks starvation and 3 weeks feeding cycle did as well as, if not better than, the constantly fed controls over one or two complete cycles, though the controls were fed more than twice the amount of feed. Three ration levels were compared using a 3-week starvation and 3-week feeding period. The only effect of increasing ration level was to decrease conversion efficiency, indicating overfeeding. Carcass analysis of moisture, fat, protein and ash showed no significant differences between the controls and an experimental group on a 3 weeks starvation, 3 weeks feeding cycle after one complete cycle. Possible mechanisms underlying the compensatory growth response are discussed.     

Starvation-Induced Thermal Tolerance as a Survival Mechanism in a Psychrophilic Marine Bacterium

Carbon-starved cultures of strain Ant-300, a psychrophilic marine vibrio isolated from the Antarctic Convergence, were compared with their nonstarved counterparts for resistance to heat. Specifically, starved and unstarved cells were exposed to 17°C, which is 4°C above the maximum growth temperature, and compared with cells maintained at the optimum temperature (5 to 7°C). Total cell counts, direct viable-cell counts, and plate counts were monitored. At a temperature of 17°C, viability (as indicated by plate counts) was lost within 40 h, with direct viable-cell counts indicating less than 5% viability at this time. However, when cells were carbon starved for 1 week prior to heat challenge, significant plateability was maintained for more than 6 days; direct viable-cell counts of starved cells maintained at 17°C indicated the presence of viable cells for at least 12 days. Because starvation is the normal physiological state of copiotrophic, heterotrophic bacteria in oligotrophic marine waters, these data suggest that starvation conditions may be a significant factor in providing heat tolerance to psychrophiles.     

The effect of amino acid starvation on nucleoside uptake and RNA synthesis in Tetrahymena

The uptake of nucleosides and the synthesis of RNA in Tetrahymena thermophila were examined following amino acid starvation. Omission of leucine, phenylalanine, or arginine from the medium resulted in a rapid decrease in the incorporation of [3H]uridine into the acid-soluble pool and acid-insoluble material (RNA). Amino acid starvation inhibited the uptake of all ribo- and deoxyribonucleosides tested but did not affect the uptake of amino acids or glucose. In addition, under the conditions used, the omission of an amino acid did not result in a large decrease in amino acid incorporation into total protein. Treatment of cells with cycloheximide or emetine gave results similar to the effects of amino acid starvation, but in these experiments the inhibition of protein synthesis was essentially complete. Nucleotide pool sizes were also measured following amino acid starvation. ATP and UTP levels were essentially unchanged, but the dTTP pool size was decreased by 40%. The decrease in RNA synthesis in vivo in the absence of an essential amino acid was reflected in the endogenous RNA synthetic activity of isolated nuclei. However, when solubilized RNA polymerase activity was measured with calf thymus DNA as template, no significant difference was observed between control and amino acid-starved cells.     

Selective changes in the protein-turnover rates and nature of growth induced in trout liver by long-term starvation followed by re-feeding

We report upon the effects of a cycle of long-term starvation followed by re-feeding on the liver-protein turnover rates and nature of protein growth in the rainbow trout (Oncorhynchus mykiss). We determined the protein-turnover rate and its relationship with the nucleic-acid concentrations in the livers of juvenile trout starved for 70 days and then re-fed for 9 days. During starvation the total hepatic-protein and RNA contents decreased significantly and the absolute protein-synthesis rate (A_S) also fell, whilst the fractional protein-synthesis rate (K_S) remained unchanged and the fractional protein-degradation rate (K_D) increased significantly. Total DNA content, an indicator of hyperplasia, and the protein:DNA ratio, an indicator of hypertrophy, both fell considerably. After re-feeding for 9 days the protein-accumulation rates (K_G, A_G) rose sharply, as did K_S, A_S, K_D, protein-synthesis efficiency (K_RNA) and the protein-synthesis rate/DNA unit (K_DNA). The total hepatic protein and RNA contents increased but still remained below the control values. The protein:DNA and RNA:DNA ratios increased significantly compared to starved fish. These changes demonstrate the high response capacity of the protein-turnover rates in trout liver upon re-feeding after long-term starvation. Upon re-feeding hypertrophic growth increased considerably whilst hyperplasia remained at starvation levels.