Variations in rRNA content of marine Vibrio spp. during starvation-survival and recovery.

The degree and temporal context of variations in ribosome content during nutrient starvation of two copiotrophic marine bacteria, Vibrio alginolyticus and Vibrio furnissii, have been examined. The organisms were starved either by nutritional shift-down or by consumption of limiting nutrients resulting from growth into stationary phase. Measurements of the amount of hybridization to 16S rRNA-specific probes revealed that the cells retained between 10 and 26% of their original rRNA content after 15 days of starvation. In V. alginolyticus, losses in stationary-phase cells occurred rapidly (1 to 2 days), whereas cells shifted into starvation remained larger and retained considerably more rRNA. The ability of V. alginolyticus to recover from starvation was assessed after cells were maintained for 2, 8, and 15 days in nutrient-depleted medium. The pattern of recovery at the level of rRNA accumulation depended upon the duration of nutrient deprivation and the manner in which it was imposed. Stationary-phase cells starved for 2 days had only slight relative increases in rRNA levels after excess nutrients were added. As the duration of starvation lengthened to 8 and 15 days, increasingly greater amounts of rRNA (30 and 70 times preenrichment values, respectively) were transcribed after nutrient enrichment. Shift-down cells recovered from 2 and 8 days of starvation without extensive rRNA production. After 15 days, nutrient enrichment caused 16S rRNA levels to increase 30-fold. The results indicate that the mechanisms controlling starvation-survival in these marine bacterial species are linked to the physiological state at the onset of starvation and that the subsequent pattern of recovery will depend upon how starvation was initiated.     

Variations in rRNA content of marine Vibrio spp. during starvation-survival and recovery.

The degree and temporal context of variations in ribosome content during nutrient starvation of two copiotrophic marine bacteria, Vibrio alginolyticus and Vibrio furnissii, have been examined. The organisms were starved either by nutritional shift-down or by consumption of limiting nutrients resulting from growth into stationary phase. Measurements of the amount of hybridization to 16S rRNA-specific probes revealed that the cells retained between 10 and 26% of their original rRNA content after 15 days of starvation. In V. alginolyticus, losses in stationary-phase cells occurred rapidly (1 to 2 days), whereas cells shifted into starvation remained larger and retained considerably more rRNA. The ability of V. alginolyticus to recover from starvation was assessed after cells were maintained for 2, 8, and 15 days in nutrient-depleted medium. The pattern of recovery at the level of rRNA accumulation depended upon the duration of nutrient deprivation and the manner in which it was imposed. Stationary-phase cells starved for 2 days had only slight relative increases in rRNA levels after excess nutrients were added. As the duration of starvation lengthened to 8 and 15 days, increasingly greater amounts of rRNA (30 and 70 times preenrichment values, respectively) were transcribed after nutrient enrichment. Shift-down cells recovered from 2 and 8 days of starvation without extensive rRNA production. After 15 days, nutrient enrichment caused 16S rRNA levels to increase 30-fold. The results indicate that the mechanisms controlling starvation-survival in these marine bacterial species are linked to the physiological state at the onset of starvation and that the subsequent pattern of recovery will depend upon how starvation was initiated.     

The phylogenetic status of Sarcobium lyticum, an obligate intracellular bacterial parasite of small amoebae

A 16S rRNA gene of the obligate intracellular bacterial parasite Sarcobium lyticum was amplified using the polymerase chain reaction in combination with site-specific primers. The amplified DNA was cloned, sequenced and compared with other bacterial 16S rRNA sequences. The analysis revealed that S. lyticum belongs to the gamma subclass of the Proteobacteria and shows the closest relationship to an intracellular Legionella species recovered by amoebal enrichment from the sputum of a patient with pneumonia. S. lyticum could be detected in situ with a fluorescent oligonucleotide probe by whole cell hybridization.     

Effects of growth phase,diel cycle and macronutrient stress on the quantification of Heterosigma akashiwo using qPCR and SHA

The development of molecular probe technologies over the last several decades has enabled more rapid and specific identification and enumeration of phytoplankton species compared to traditional technologies, such as light microscopy. Direct comparisons of these methods with respect to physiological status, however, are sparse. Here we directly compare quantitative real-time PCR (qPCR) and sandwich hybridization assay (SHA) for enumerating the raphidophyte Heterosigma akashiwo at several points during its growth phase, over a diel cycle and with macronutrient stress in laboratory cultures. To ensure consistency between comparisons, a single cellular homogenate was generated from each culture and split for analysis by qPCR and SHA. Since the homogenate was generated from the same number of cells during each experiment, results reflect changes in nucleic acid content (rRNA and DNA) at each time point or in response to environmental conditions relative to a reference sample. Results show a greater level of precision in SHA results which contributed to significant (2–3 fold) differences in rRNA content per cell in several of these analyses. There was significantly greater rRNA content during lag and exponential phases compared to stationary phase cultures, and a significant decrease in rRNA content during the light cycle compared to cells harvested in the dark. In contrast, there were no significant differences in DNA content per cell as determined by qPCR over a diel cycle or during different growth phases. There was also no decrease in either rRNA or DNA content for cultures under low P conditions compared to nutrient replete conditions. However, both rRNA and DNA content were significantly lower under N stress when compared to nutrient replete conditions. Results of this study suggest that growth stage, nutrient stress and cell cycle may impact molecular analyses, and that physiological status should be taken into account when using these methods for HAB monitoring.     

Changes in cytoplasmic and chloroplast ribosomal ribonucleic acid during the cell cycle of Chlamydomonas reinhardtii

Polyacrylamide gel electrophoresis of isolated cytoplasmic and chloroplast ribosomal ribonucleic acid species during the synchronous vegetative cell cycle of the eukaryote Chlamydomonas reinhardtii suggests that a separate control of cytoplasmic and chloroplast rRNA might exist. It was found that the amount of cytoplasmic rRNA linearly increased during the entire G₁ phase of the cell cycle, whereas chloroplast rRNA accumulated only through 70% of the G₁ period. The amount of cytoplasmic rRNA per mother cell remained constant during nuclear DNA synthesis but a gradual loss of chloroplast rRNA was noted at this time. A significant decline in all four rRNA species occurred at the time of cell division.     

Degradation of rRNA in Salmonella strains: a novel mechanism to regulate the concentrations of rRNA and ribosomes.

We have previously shown that the 23S rRNA of Salmonella strains is highly fragmented by specific enzyme cleavages. In this article, we report that 23S rRNA of Salmonella strains is rapidly degraded as the cells enter the stationary phase. More than 90% of the 23S rRNA is degraded when the cells reach the stationary phase. The rate of degradation of 23S rRNA correlated with its degree of fragmentation. This degradation is probably mediated by newly synthesized protein factor(s), since treatment with chloramphenicol or rifampin inhibits the rRNA degradation. We propose that degradation of 23S rRNA is a novel mechanism in the regulation of the bacterial 23S rRNA and ribosome concentration and that this additional regulatory mechanism provides some selective advantage to cells.     

In Situ Detection of an Uncultured Predominant Bacillus in Dutch Grassland Soils

Uncultured predominant Bacillus ribotype DA001 in Dutch Drentse A grassland soils, as revealed by its 16S rRNA sequence, was detected in soil by fluorescent whole-cell in situ hybridization. A prominent rod-shaped cell type was identified in bacterial suspensions prepared from soil by a multiple 16S rRNA probing approach.     

Quantification of Expression of Staphylococcus epidermidis Housekeeping Genes with Taqman Quantitative PCR during In Vitro Growth and under Different Conditions

The aims of the present study were (i) to develop and test a sensitive and reproducible method for the study of gene expression in staphylococci and (ii) to study the expression of five housekeeping genes which are involved in nucleic acid metabolism (gmk, guanylate kinase; the dihydrofolate reductase [DHFR] gene), glucose metabolism (tpi, triosephosphate isomerase), and protein metabolism (the 16S rRNA gene; hsp-60, heat-shock protein 60) during in vitro exponential and stationary growth. A modified method for instant mRNA isolation was combined with gene quantification via Taqman real-time quantitative PCR. The detection limit of our method was 10 copies of RNA. The average intersample variability was 16%. A 10-fold increase in the expression of the hsp-60 gene was induced by exposure to a 10 degrees C heat shock (37 to 47 degrees C) for 10 min. During in vitro growth, the expression of all five housekeeping genes showed rapid up-regulation after inoculation of the bacteria in brain heart infusion medum and started to decline during the mid-exponential-growth phase. Maximal gene expression was 110- to 300-fold higher than gene expression during stationary phase. This indicates that housekeeping metabolism is a very dynamic process that is extremely capable of adapting to different growth conditions. Expression of the 16S rRNA gene decreases significantly earlier than that of other housekeeping genes. This confirms earlier findings for Escherichia coli that a decline in bacterial ribosomal content (measured by 16S rRNA gene expression) precedes the decline in protein synthesis (measured by mRNA expression).     

Species-Specific Detection of Vibrio anguillarum in Marine Aquaculture Environments by Selective Culture and DNA Hybridization

Methods for specific detection of Vibrio anguillarum in complex microbial communities within diverse marine aquaculture environments were evaluated. A system for the detection of culturable cells based on the combined use of a selective medium and a nonradioactively labeled oligodeoxynucleotide complementary to 16S rRNA was developed. Four hundred fourteen bacterial cultures were evaluated in order to assess the specificity of the method. When both the selective medium and the specific probe gave positive results, the cultures were always identified as V. anguillarum. The selectivity for colony hybridization was 1 V. anguillarum cell in 10,000 total bacterial cells in environmental samples. The utility of the method was also compared with detection by dot blot hybridization of either raw DNA purified from environmental samples or PCR-amplified DNA of 16S rRNA genes, using universal eubacterial primers. The post-PCR hybridization was more sensitive (8 x 10(sup2) cells) than direct hybridization of the whole purified DNA (10(sup6) cells). However, the selective medium-probe combined method was as sensitive as post-PCR hybridization, albeit more specific.     

Does the rate of ribosomal RNA synthesis vary depending on the number of nucleoli in a nucleus?

Cultured kidney cells of Xenopus laevis were pulse-labeled with [³H]uridine for 10, 20 and 30 min during their logarithmic growth phase and then processed for autoradiography. The labeled cells were assigned into two categories, one- and two-nucleolated cells, and the rate of ribosomal RNA (rRNA) synthesis was measured by counting the number of grains in nucleoli. The results obtained revealed that a two-nucleolated cell incorporated significantly much more radioactivity into its nucleoli than did a one-nucleolated partner for all the periods examined. Cells of these different nucleolar types, however, contained essentially the same amount of rDNA (DNA complementary to rRNA) as estimated by in situ hybridization with [¹²⁵I]rRNA.Although it remains to be proved that the observed increase in incorporation represents the increased rate of rRNA synthesis in two-nucleolated cells, the present findings seem to be very interesting, since they might indicate that the activity of rRNA genes is in some way regulated or affected by their spatial relationship in a cell nucleus.     

Analysis of the microbial community structure in a membrane bioreactor during initial stages of filtration

Membrane biofouling was investigated during the early stages of filtration in a laboratory-scale membrane bioreactor operated on molasses wastewater. The bacterial diversity and composition of the membrane biofilm and activated sludge were analyzed using terminal restriction fragment length polymorphism coupled with 16S rRNA clone library construction and sequencing. The amount of extracellular polymeric substances produced by bacteria was investigated using spectroscopic methods. The results reveal that the bacterial community of activated sludge differs significantly from that of the membrane biofilm, especially at the initial phase. Phylogenetic analysis based on 16S rRNA gene sequences identified 25 pioneer OTUs responsible for membrane surface colonization. Also, the relationship between the identified bacterial strains and the system specifications was explored.     

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.