Prophages in marine bacteria: dangerous molecular time bombs or the key to survival in the seas?

Bacteriophages are realized to be numerous and important components of oceanic food webs principally because of their lytic capabilities. The subtle changes that temperate phages impart to their hosts in the oceans are far less understood. Occurrences of lysogeny in the oceans correlate well with conditions unfavorable for rapid host growth. In coliphage lambda, phage encoded repressors have been shown to modulate host metabolic gene expression and phenotype, resulting in economizing host energy expenditure. Comparison of lysogenized marine bacteria to the uninfected hosts indicated that prophage acquisition is correlated with host metabolic gene suppression. Screening 113 marine bacterial genomes for prophages yielded 64 prophage-like elements, 21 of which strongly resembled gene transfer agents (GTAs). The remaining 39 putative prophages had a relatively high incidence of transcriptional regulatory and repressor-like proteins (approximately 2/40 kb prophage sequence) compared to lytic marine phages (approximately 0.25/40 kb phage sequence). Here, it has been hypothesized that marine prophages directly contribute to host survival in unfavorable environments by suppression of unneeded metabolic activities. It has been further suggested that such metabolic downshifts are the result of phage-encoded repressors and transcriptional regulators acting directly on host genes. Finally, the widespread occurrence of GTAs may be an efficient mechanism for horizontal gene transfer in the oceans.

Comparison of lysogeny (prophage induction) in heterotrophic bacterial and Synechococcus populations in the Gulf of Mexico and Mississippi River plume

Lysogeny has been documented as a fundamental process occurring in natural marine communities of heterotrophic and autotrophic bacteria. Prophage induction has been observed to be prevalent during conditions of low host abundance, but factors controlling the process are poorly understood. A research cruise was undertaken to the Gulf of Mexico during July 2005 to explore environmental factors associated with lysogeny. Ambient physical and microbial parameters were measured and prophage induction experiments were performed in contrasting oligotrophic Gulf and eutrophic Mississippi plume areas. Three of 11 prophage induction experiments in heterotrophic bacteria (27%) demonstrated significant induction in response to Mitomycin C. In contrast, there was significant Synechococcus cyanophage induction in seven of nine experiments (77.8%). A strong negative correlation was observed between lysogeny and log-transformed activity measurements for both heterotrophic and autotrophic populations (r=-0.876, P=0.002 and r=-0.815, P=0.025, respectively), indicating that bacterioplankton with low host growth favor lysogeny. Multivariate statistical analyses indicated that ambient level of viral abundance and productivity were inversely related to heterotrophic prophage induction and both factors combined were most predictive of lysogeny (rho=0.899, P=0.001). For Synechococcus, low ambient cyanophage abundance was most predictive of lysogeny (rho=0.862, P=0.005). Abundance and productivity of heterotrophic bacteria was strongly inversely correlated with salinity, while Synechococcus was not. This indicated that heterotrophic bacterial populations were well adapted to the river plume environments, thus providing a possible explanation for differences in prevalence of lysogeny observed between the two populations.

Rapid screening of a large insert BAC library for specific 16S rRNA genes using TRFLP

It is widely believed that the vast majority of microbes in the environment have-yet-to-be cultured using standard techniques. Bulk DNA from microbial communities is therefore often cloned into large insert vectors (e.g. bacterial artificial chromosomes [BAC] or cosmids) in order to study the genetic properties of these as yet (un)-cultured bacteria. In a typical BAC experiment, tens of thousands of clones are generated with only a small fraction of colonies containing the target(s) of interest. Efficient screening methodologies are therefore needed to allow targeted clone isolation. In this paper, we describe a rapid, inexpensive protocol that allows for the identification of specific 16S ribosomal RNA genes in a metagenomic library arrayed into 384-well microtiter plates. The rapid screening protocol employs Terminal Restriction Fragment Length Polymorphism (TRFLP) analysis to identify wells containing specific T-RF peaks. A nested approach using multiplexed samples of 384, 48, 8, and single colony analysis is described and applied in order to survey a BAC library generated from a marine microbial community off the coast of New Jersey. Screening revealed a total of 50 different 16 rRNA genes within the BAC library. Overall, the multiplexing format provided a simple, cost effective methodology for detecting clones bearing a target gene of interest in a large clone library. However, the limitations of screening BAC libraries using PCR methodologies and recommendations for improved screening efficiency using this approach are also discussed.

Phytoplankton-group specific quantitative polymerase chain reaction assays for RuBisCO mRNA transcripts in seawater

The gene for the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase (rbcL) has been shown to be a useful target for molecular assays that quantify form- or clade-specific RNA transcript concentrations as a proxy for the carbon fixation activity of marine phytoplankton. To improve the phylogenetic specificity and sensitivity of RNA probe hybridization methods, a quantitative reverse transcription-polymerase chain reaction (RT-PCR) assay has been reported for diatom and pelagophyte rbcL RNA. Here we detail enhancements made to this PCR method and development of additional assays to specifically quantify rbcL expression from haptophytes, Synechococcus and high-light Prochlorococcus. In vitro RNA transcripts were tested to demonstrate specificity and quantitative accuracy. Application of these methods on seawater samples from two depth profiles in the northern Gulf of Mexico showed a fair degree of agreement between PCR and hybridization results, with results for the chromophytic or form ID rbcL-containing organisms having better agreement between the two methods. Diatoms and other heterokonts were shown to be the primary carbon fixers at these locations by PCR, in agreement with greater form ID rbcL RNA measured by hybridization.

A nucleic acid sequence-based amplification assay for real-time detection of norovirus genogroup II

AIMS

To use molecular beacon based nucleic acid sequence-based amplification (NASBA) to develop a rapid, sensitive, specific detection method for norovirus (NV) genogroupII (GII).

METHODS AND RESULTS

A method to detect NV GII from environmental samples using real-time NASBA was developed. This method was routinely sensitive to 100 copies of target RNA and intermittent amplification occurred with as few as 10 copies. Quantitative estimates of viral load were possible over at least four orders of magnitude.

CONCLUSIONS

The NASBA method described here is a reliable and sensitive assay for the detection of NV. This method has the potential to be linked to a handheld NASBA device that would make this real-time assay a portable and inexpensive alternative to bench-top, lab-based assays.

SIGNIFICANCE AND IMPACT OF THE STUDY

The development of the real-time NASBA assay described here has resulted in a simple, rapid (<1 h), convenient testing format for NV. To our knowledge, this is the first example of a molecular beacon based NASBA assay for NV.

The genome of deep-sea vent chemolithoautotroph Thiomicrospira crunogena XCL-2

Presented here is the complete genome sequence of Thiomicrospira crunogena XCL-2, representative of ubiquitous chemolithoautotrophic sulfur-oxidizing bacteria isolated from deep-sea hydrothermal vents. This gammaproteobacterium has a single chromosome (2,427,734 base pairs), and its genome illustrates many of the adaptations that have enabled it to thrive at vents globally. It has 14 methyl-accepting chemotaxis protein genes, including four that may assist in positioning it in the redoxcline. A relative abundance of coding sequences (CDSs) encoding regulatory proteins likely control the expression of genes encoding carboxysomes, multiple dissolved inorganic nitrogen and phosphate transporters, as well as a phosphonate operon, which provide this species with a variety of options for acquiring these substrates from the environment. Thiom. crunogena XCL-2 is unusual among obligate sulfur-oxidizing bacteria in relying on the Sox system for the oxidation of reduced sulfur compounds. The genome has characteristics consistent with an obligately chemolithoautotrophic lifestyle, including few transporters predicted to have organic allocrits, and Calvin-Benson-Bassham cycle CDSs scattered throughout the genome.

Environmental factors that influence the transition from lysogenic to lytic existence in the phiHSIC/Listonella pelagia marine phage-host system

The marine phage varphiHSIC has been previously reported to enter into a pseudolysogenic-like interaction with its host Listonella pelagia. This phage-host system displays behaviors that are characteristic of both pseudolysogeny and lysogeny including a high rate of spontaneous induction and chromosomal integration of the prophage. To determine what parameters may influence the transition from lysogenic to lytic existence in the varphiHSIC/L. pelagia phage-host system, cultures of this organism were incubated under different environmental conditions, while host cell growth and bacteriophage production were monitored. The environmental parameters tested included salinity, temperature, a rapid temperature shift, and degree of culture aeration. The highest titers of phage were produced by HSIC-1a cells grown in high-salinity nutrient artificial seawater media (67 ppt with a natural salinity equivalent of 57 ppt) or those cultured in highly aerated nutrient artificial seawater media (cultures shaken at 300 rpm). Conversely, the lowest titers of phage were produced under low salinity or rate of aeration. In general, conditions that stimulated growth resulted in greater lytic phage production, whereas slow growth favored lysogeny. These results indicate that elevated salinity and aeration influenced the switch from lysogenic to lytic existence for the phage varphiHSIC. These results may have implications for environmental controls of the lysogenic switch in natural populations of marine bacteria.

Development and applications of microbial ecogenomic indicators for monitoring water quality: report of a workshop assessing the state of the science, research needs and future directions

This article brings forth recommendations from a workshop sponsored by the U.S. Environmental Protection Agency's Science to Achieve Results (STAR) and Environmental Monitoring and Assessment (EMAP) Programs and by the Council of State Governments, held during May 2002 in Kansas City, Kansas. The workshop assembled microbial ecologists and environmental scientists to determine what research and science is needed to bring existing molecular biological approaches and newer technologies arising from microbial genomic research into environmental monitoring and water quality assessments. Development of genomics and proteomics technologies for environmental science is a very new area having potential to improve environmental water quality assessments. The workshop participants noted that microbial ecologists are already using molecular biological methods well suited for monitoring and water quality assessments and anticipate that genomics-enabled technologies could be made available for monitoring within a decade. Recommendations arising from the workshop include needs for (i) identification of informative microbial gene sequences, (ii) improved understandings of linkages between indicator taxa, gene expression and environmental condition, (iii) technological advancements towards field application, and (iv) development of the appropriate databases.

Complete genome sequence of phiHSIC, a pseudotemperate marine phage of Listonella pelagia

The genome for the marine pseudotemperate member of the Siphoviridae phiHSIC has been sequenced using a combination of linker amplification library construction, restriction digest library construction, and primer walking. phiHSIC enters into a pseudolysogenic relationship with its host, Listonella pelagia, characterized by sigmoidal growth curves producing >10(9) cells/ml and >10(11) phage/ml. The genome (37,966 bp; G+C content, 44%) contained 47 putative open reading frames (ORFs), 17 of which had significant BLASTP hits in GenBank, including a beta subunit of DNA polymerase III, a helicase, a helicase-like subunit of a resolvasome complex, a terminase, a tail tape measure protein, several phage-like structural proteins, and 1 ORF that may assist in host pathogenicity (an ADP ribosyltransferase). The genome was circularly permuted, with no physical ends detected by sequencing or restriction enzyme digestion analysis, and lacked a cos site. This evidence is consistent with a headful packaging mechanism similar to that of Salmonella phage P22 and Shigella phage Sf6. Because none of the phage-like ORFs were closely related to any existing phage sequences in GenBank (i.e., none more than 62% identical and most <25% identical at the amino acid level), phiHSIC is unique among phages that have been sequenced to date. These results further emphasize the need to sequence phages from the marine environment, perhaps the largest reservoir of untapped genetic information.

Marine phage genomics: what have we learned?

Marine phages are the most abundant and diverse form of life on the planet, and their genomes have been described as the largest untapped reservoir of genomic information. To date, however, the complete genome sequences of only 17 marine phage are known. Nevertheless, these genomes have revealed some interesting features, including the presence of photosynthetic genes in cyanophage and common patterns of genomic organization. Intriguing findings are also being made from studies of the uncultivated marine viral community genome ('metavirome'). The greatest challenge in interpreting the biology of these phages, and for making comparisons with their terrestrial counterparts, is the high proportion of unidentifiable open reading frames (approximately 60%). Future studies are likely to focus on sequencing more marine phage genomes from disparate hosts and diverse environments and on further basic studies of the biology of existing marine phages.

Effect of nutrient addition and environmental factors on prophage induction in natural populations of marine synechococcus species

A series of experiments were conducted with samples collected in both Tampa Bay and the Gulf of Mexico to assess the impact of nutrient addition on cyanophage induction in natural populations of Synechococcus sp. The samples were virus reduced to decrease the background level of cyanophage and then either left untreated or amended with nitrate, ammonium, urea, or phosphate. Replicate samples were treated with mitomycin C to stimulate cyanophage induction. In five of the nine total experiments performed, cyanophage induction was present in the non-nutrient-amended control samples. Stimulation of cyanophage induction in response to nutrient addition (phosphate) occurred in only one Tampa Bay sample. Nutrient additions caused a decrease in lytic (or control) phage production in three of three offshore stations, in one of three estuarine experiments, and in a lysogenic marine Synechococcus in culture. These results suggest that the process of cyanophage induction as an assay of Synechococcus lysogeny was not inorganically nutrient limited, at least in the samples examined. More importantly, it was observed that the level of cyanophage induction (cyanophage milliliter(-1)) was inversely correlated to Synechococcus and cyanophage abundance. Thus, the intensity of the prophage induction response is defined by ambient population size and cyanophage abundance. This corroborates prior observations that lysogeny in Synechococcus is favored during times of low host abundance.

Increased precision of microbial RNA quantification using NASBA with an internal control

Detection and quantification of low abundance target RNA has wide utility in the fields of clinical diagnostics, environmental monitoring, gene expression analysis, and biodefense. Nucleic acid based sequence amplification (NASBA) is an isothermal amplification method that provides the sensitivity needed for these applications. However, the requirement for three separate enzymes in NASBA often results in a greater variability between replicate samples than that seen in PCR-based assays. To overcome this problem, we have adapted the bioMérieux Nuclisens Basic Kit and Nuclisens EasyQ Analyzer along with the introduction of a synthetic internal control RNA (IC-RNA) for quantification of potentially any RNA sequence. Using the rbcL gene from the Florida red tide organism Karenia brevis as our target, we describe a simple method to accurately quantify the native target by computing the ratio of the time to positivity (TTP) values for both the wild-type and IC-RNA, and plotting this ratio against the starting number of target molecules or cells. By utilizing this simple method, we have significantly increased our accuracy and precision of prediction over the standard TTP calculations.

Development and evaluation of a method to detect and quantify enteroviruses using NASBA and internal control RNA (IC-NASBA)

We have developed a rapid, sensitive, and specific assay for the detection and quantification of enteroviruses using nucleic acid sequence-based amplification (NASBA). The inclusion of an internal control (IC) increased the precision and accuracy of the method over a standard NASBA assay and provided a way to detect assay inhibition. The assay was sensitive to 10 viral particles with amplification and detection occurring in as little as 18 min. The assay detected a variety of different enteroviruses to the exclusion of non-target viruses. The standard NASBA method resulted in predictions of viral load to within an order of magnitude of the expected number, as compared with prediction to within less than a half order of magnitude using the IC-NASBA method. Rapid and sensitive detection of enteroviruses is important in both clinical samples to diagnose illness and in environmental samples to assess risk of wastewater contamination and potential health hazards.

Geochemical rate-RNA integration study: ribulose-1,5-bisphosphate carboxylase/oxygenase gene transcription and photosynthetic capacity of planktonic photoautotrophs

A pilot field experiment to assess the relationship between traditional biogeochemical rate measurements and transcriptional activity of microbial populations was carried out at the LEO 15 site off Tuckerton, N.J. Here, we report the relationship between photosynthetic capacity of autotrophic plankton and transcriptional activity of the large subunit gene (rbcL) for ribulose-1,5-bisphosphate carboxylase/oxygenase (RubisCO), the enzyme responsible for primary carbon fixation during photosynthesis. Similar diel patterns of carbon fixation and rbcL gene expression were observed in three of four time series, with maxima for photosynthetic capacity (P(max)) and rbcL mRNA occurring between 10 a.m. and 1 p.m. The lowest P(max) and rbcL levels were detected between 6 p.m. and 10:30 p.m. A significant correlation was found between P(max) and form ID rbcL mRNA (R(2) = 0.56) and forms IA and IB (R(2) = 0.41 and 0.47, respectively). The correlation between the abundance of "diatom" rbcL and P(max) mRNA was modest (R(2) = 0.49; n = 12) but improved dramatically (R(2) = 0.97; n = 10) upon removal of two outliers which represented afternoon samples with high P(max) but lower mRNA levels. Clone libraries from reverse transcription-PCR-amplified rbcL mRNA indicated the presence of several chromophytic algae (diatoms, prymnesiophytes, and chrysophytes) and some eukaryotic green flagellates. Analogous results were obtained from amplified small rRNA sequences and secondary pigment analysis. These results suggest that diatoms were a major contributor to carbon fixation at LEO 15 at the time of sampling and that photosynthetic carbon fixation was partially controlled by transcriptional regulation of the RubisCO gene.

Detection and quantification of the red tide dinoflagellate Karenia brevis by real-time nucleic acid sequence-based amplification

Nucleic acid sequence-based amplification (NASBA) is an isothermal method of RNA amplification that has been previously used in clinical diagnostic testing. A real-time NASBA assay has been developed for the detection of rbcL mRNA from the red tide dinoflagellate Karenia brevis. This assay is sensitive to one K. brevis cell and 1.0 fg of in vitro transcript, with occasional detection of lower concentrations of transcript. The assay did not detect rbcL mRNA from a wide range of nontarget organisms and environmental clones, while 10 strains (all tested) of K. brevis were detected. By the use of standard curves based on time to positivity, concentrations of K. brevis in environmental samples were predicted by NASBA and classified into different levels of blooms per the Florida Fish and Wildlife Conservation Commission (FWC) system. NASBA classification matched FWC classification (based on cell counts) 72% of the time. Those samples that did not match were off by only one class. NASBA is sensitive, rapid, and effective and may be used as an additional or alternative method to detect and quantify K. brevis in the marine environment.

Pathogenic human viruses in coastal waters

This review addresses both historical and recent investigations into viral contamination of marine waters. With the relatively recent emergence of molecular biology-based assays, a number of investigations have shown that pathogenic viruses are prevalent in marine waters being impacted by sewage. Research has shown that this group of fecal-oral viral pathogens (enteroviruses, hepatitis A viruses, Norwalk viruses, reoviruses, adenoviruses, rotaviruses, etc.) can cause a broad range of asymptomatic to severe gastrointestinal, respiratory, and eye, nose, ear, and skin infections in people exposed through recreational use of the water. The viruses and the nucleic acid signature survive for an extended period in the marine environment. One of the primary concerns of public health officials is the relationship between the presence of pathogens and the recreational risk to human health in polluted marine environments. While a number of studies have attempted to address this issue, the relationship is still poorly understood. A contributing factor to our lack of progress in the field has been the lack of sensitive methods to detect the broad range of both bacterial and viral pathogens. The application of new and advanced molecular methods will continue to contribute to our current state of knowledge in this emerging and important field.

Marine phage genomics

Marine phages are the most abundant biological entities in the oceans. They play important roles in carbon cycling through marine food webs, gene transfer by transduction and conversion of hosts by lysogeny. The handful of marine phage genomes that have been sequenced to date, along with prophages in marine bacterial genomes, and partial sequencing of uncultivated phages are yielding glimpses of the tremendous diversity and physiological potential of the marine phage community. Common gene modules in diverse phages are providing the information necessary to make evolutionary comparisons. Finally, deciphering phage genomes is providing clues about the adaptive response of phages and their hosts to environmental cues.

Seasonal variation in lysogeny as depicted by prophage induction in Tampa Bay, Florida

A seasonal study of the distribution of lysogenic bacteria in Tampa Bay, Florida, was conducted over a 13-month period. Biweekly water samples were collected and either were left unaltered or had the viral population reduced by filtration (pore size, 0.2 micro m) and resuspension in filtered (pore size, 0.2 micro m) water. Virus-reduced and unaltered samples were then treated by adding mitomycin C (0.5 micro g ml(-1)) to induce prophage or were left untreated. In order to test the hypothesis that prophage induction was phosphate limited, additional induction experiments were performed in the presence and absence of phosphate. Induction was assessed as an increase in viral direct counts, relative to those obtained in controls, as detected by epifluorescence microscopy. Induction of prophage was observed in 5 of 25 (20%) unaltered samples which were obtained during or after the month of February, paralleling the results from a previous seasonal study. Induction of prophage was observed in 9 of 25 (36%) of the virus-reduced samples, primarily those obtained in the winter months, which was not observed in a prior seasonal study (P. K. Cochran and J. H. Paul, Appl. Environ. Microbiol. 64:2308-2312, 1998). Induction was noted in the months of lowest bacterial and primary production, suggesting that lysogeny was favored under conditions of poor host growth. Phosphate addition enabled prophage induction in two of nine (22%) experiments. These results indicate that prophage induction may occasionally be phosphate limited or respond to increases in phosphate concentration, suggesting that phosphate concentration may modulate the lysogenic response of natural populations.

Real-time PCR quantification of rbcL (ribulose-1,5-bisphosphate carboxylase/oxygenase) mRNA in diatoms and pelagophytes

Transcriptional activity is often used as a surrogate for gene expression in environmental microbial communities. We developed a real-time PCR assay in which the ABI-Prism (PE Applied Biosystems) detection system is used for quantification of large-subunit ribulose-1,5-bisphosphate caboxylase/oxygenase (rbcL) mRNA in diatoms and pelagophytes both in cultures and from natural phytoplankton communities. Plasmid DNA containing rbcL inserts, as well as in vitro transcribed mRNA of the plasmids, was used to generate standard curves with a dynamic range of more than 6 orders of magnitude with high accuracy and precision (R(2) = 0.998). Expression levels in a cultured diatom (Phaeodactylum tricornutum) were quantified through one light-dark cycle by using traditional 35S-labeled oligonucleotide hybridization and real-time PCR. The mRNA levels detected by the two techniques were similar and correlated well (R(2) = 0.95; slope = 1.2). The quantities obtained by hybridization were slightly, yet significantly, larger (t = 5.29; P = 0.0011) than the quantities obtained by real-time PCR. This was most likely because partially degraded transcripts were not detected by real-time PCR. rbcL mRNA detection by real-time PCR was 3 orders of magnitude more sensitive than rbcL mRNA detection by hybridization. Diatom and pelagophyte rbcL mRNAs were also quantified in a profile from an oligotrophic site in the Gulf of Mexico. We detected the smallest amount of diatom rbcL expression in the surface water and maximum expression at a depth that coincided with the depth of the subsurface chlorophyll maximum. These results indicate that real-time PCR may be utilized for quantification of microbial gene expression in the environment.

Detection, quantitation and identification of enteroviruses from surface waters and sponge tissue from the Florida Keys using real-time RT-PCR

A method was developed for the quantitative detection of pathogenic human enteroviruses from surface waters in the Florida Keys using Taqman (R) one-step Reverse transcription (RT)-PCR with the Model 7700 ABI Prism (R) Sequence Detection System. Viruses were directly extracted from unconcentrated grab samples of seawater, from seawater concentrated by vortex flow filtration using a 100 kD filter and from sponge tissue. Total RNA was extracted from the samples, purified and concentrated using spin-column chromatography. A 192-196 base pair portion of the 5' untranscribed region was amplified from these extracts. Enterovirus concentrations were estimated using real-time RT-PCR technology. Nine of 15 sample sites or 60% were positive for the presence of pathogenic human enteroviruses. Considering only near-shore sites, 69% were positive with viral concentrations ranging from 9.3 viruses/ml to 83 viruses/g of sponge tissue (uncorrected for extraction efficiency). Certain amplicons were selected for cloning and sequencing for identification. Three strains of waterborne enteroviruses were identified as Coxsackievirus A9, Coxsackievirus A16, and Poliovirus Sabin type 1. Time and cost efficiency of this one-step real-time RT-PCR methodology makes this an ideal technique to detect, quantitate and identify pathogenic enteroviruses in recreational waters.

Lysogeny in marine Synechococcus

Viral infection of bacteria can be lytic, causing destruction of the host cell, or lysogenic, in which the viral genome is instead stably maintained as a prophage within its host. Here we show that lysogeny occurs in natural populations of an autotrophic picoplankton (Synechococcus) and that there is a seasonal pattern to this interaction. Because lysogeny confers immunity to infection by related viruses, this process may account for the resistance to viral infection seen in common forms of autotrophic picoplankton.