Gene Transfer by Transduction in the Marine Environment

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Applied and Environmental Microbiology, August 1998, p. 2780-2787, Vol. 64, No. 8
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Gene Transfer by Transduction in the Marine Environment

Sunny C. Jiang and John H. Paul^*

Marine Science Department, University of South Florida, St. Petersburg, Florida 33701

Received 6 January 1998/Accepted 11 May 1998

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

To determine the potential for bacteriophage-mediated gene transfer in the marine environment, we established transductionsystems by using marine phage host isolates. Plasmid pQSR50, whichcontains transposon Tn5 and encodes kanamycin and streptomycinresistance, was used in plasmid transduction assays. Both marinebacterial isolates and concentrated natural bacterial communitieswere used as recipients in transduction studies. Transductantswere detected by a gene probe complementary to the neomycin phosphotransferase(nptII) gene in Tn5. The transduction frequencies ranged from1.33 × 10⁷ to 5.13 × 10⁹ transductants/PFU in studies performed with the bacterial isolates.With the mixed bacterial communities, putative transductants weredetected in two of the six experiments performed. These putativetransductants were confirmed and separated from indigenous antibiotic-resistantbacteria by colony hybridization probed with the nptII probe andby PCR amplification performed with two sets of primers specificfor pQSR50. The frequencies of plasmid transduction in the mixedbacterial communities ranged from 1.58 × 10⁸ to 3.7 × 10⁸ transductants/PFU. Estimates of the transduction rate obtainedby using a numerical model suggested that up to 1.3 × 10¹⁴ transduction events per year could occur in the Tampa Bay Estuary.The results of this study suggest that transduction could be animportant mechanism for horizontal gene transfer in the marineenvironment.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

A virus is little more than nucleic acid encapsulated in a protein coat. The recent discovery of the abundance of virusesin the marine environment (5, 14, 42, 47, 48) has ledto speculation regarding the involvement of viruses in gene transfer.In the process of viral propagation, viruses transfer nucleicacid synthesized in one bacterium to another bacterium. If a virusinfecting a new host contains genetic material from the previoushost rather than its own DNA, the extra genetic information maybe transmitted to the new host, resulting in transduction.

Bacteriophage-mediated horizontal transduction has been known for nearly half a century (55). Transduction has been foundto occur in many phage-host systems (6), and well-studied transductionsystems have been routinely used as molecular cloning tools (37).However, in most transduction studies workers have focused onlyon the development of tools for better understanding bacterialgenetics (3, 7, 9, 25, 26, 34, 41, 49). Therole of phage transduction in microbial ecology was not an areaof interest until very recently.

To assess the risk associated with the spread of genetically engineered microorganisms in the environment, the potential forgene transfer by transduction was studied in soil and freshwaterenvironments. Using an Escherichia coli-phage P1 transductionsystem, Zeph et al. (54) studied transduction in sterile andnonsterile soils. The results of these authors demonstrated thattransduction occurred in the soil and that the resulting transductantssurvived in soil environments for 28 days. Almost all studiesof transduction in aquatic environments have been performed byMiller's group (for a review see reference 29). These researchersdemonstrated that both chromosomal and plasmid DNAs of Pseudomonasaeruginosa were transduced during in situ incubation in a freshwaterlake (31, 36, 39, 40). Cell-free phage lysates, as wellas temperate phages spontaneously released from lysogens, werecapable of transduction (40). Also, both lysogenic and nonlysogenicbacteria can serve as recipients, but lysogenic recipients havehigher transducing frequencies, possibly due to lysogenic protectionfrom lysis (homoimmunity [29]). More recently, Ripp and Miller(35) also suggested that the presence of suspended particulatesin the water column facilitates transduction by bringing the hostand phage into close contact with each other.

Little is known about transduction in the marine environment. Although transducing phages have been isolated from seawaterpreviously (16, 23, 24), the focus of these studies wasto develop a gene transfer system to study the genetics of Vibriospp. rather than to investigate the potential for gene transferin the environment.

Viruses are abundant and active members of microbial ecosystems. The dynamic interactions of viruses with their hosts maycontribute significantly to the genetic diversity and compositionof microbial populations. For many years, studies of gene transferin the environment have largely focused on the process of conjugation(2, 15, 32) and transformation (13, 33, 43). Genetransfer via transduction was considered negligible because ofthe lytic effect of phage infection (29). However, Zeph et al.(54) suggested that gene transduction is as important or moreimportant than conjugation and transformation in the environment.In contrast to transforming DNA, transducing DNA is packaged insidephage capsids, which prevents nuclease degradation. Thus, virusesmay serve as reservoirs for exogenous genes (44).

To estimate the potential for transduction in the marine environment, we developed marine transduction systems by using marinephage host isolates. Transduction assays were performed by usingmarine bacterial isolates, as well as mixed natural bacterialcommunities, as recipients. This work established that transductionis a mechanism for horizontal gene transfer among marine microbialcommunities.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Bacteria, phages, and plasmids. The bacteria, phages, and plasmids used in this study are listed in Table 1. Marine bacterial strains HSIC and D1B were isolatedfrom Mamala Bay, Hawaii, on artificial seawater (ASWJP) agar platescontaining 5 g of peptone per liter and 1 g of yeast extract perliter. HSIC is an unidentified gram-negative coccus, while D1Bis a gram-negative slender rod which was identified as a Flavobacteriumsp. by using an API-NFT test kit (BioMerieux Vitek, Inc., Hazelwood,Mo.). Phages T- $phi$ HSIC and T- $phi$ D1B were isolated by using HSIC andD1B as hosts, respectively. Both of these phages are temperateand contain double-stranded DNA. Detailed information about thesephages and their hosts has been published elsewhere (17).

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TABLE 1. Bacteria, plasmids, and phages used in this study

E. coli RM1259 contains plasmid pQSR50, which encodes resistance to kanamycin and streptomycin. The kanamycin resistance gene,nptII, is on transposon Tn5. A detailed description of this plasmidand a plasmid map have been published by Meyer et al. (27).E. coli RM1259 was used as a plasmid donor in triparental mating,and E. coli CA60 was used as a helper strain for triparental mating(52). E. coli CA60 contains a conjugative plasmid, pNJ5000,which encodes tetracycline resistance. HOPE-1 and HOPE-2 are wild-typestrain HSIC and D1B derivatives containing plasmid pQSR50, respectively,which was introduced into the bacterial cells by triparental mating(see below).

Plasmid pQSR50 contains a Tn5 transposon insertion which codes for the neomycin phosphotransferase gene (nptII). Plasmid pNJ5000has a mobilizing function and was used as a helper plasmid formobilization of other plasmids.

Triparental mating. Rifampin-resistant mutants of bacterial strains HSIC and D1B were selected on ASWJP nutrient plates containing 500 µg of rifampinper ml and were used as recipients for triparental mating. Onemilliliter of an overnight rifampin-resistant cell culture wastransferred to 10 ml of ASWJP nutrient broth containing 500 µgof rifampin per ml, and the preparation was incubated with shakinguntil the optical density at 600 nm was 0.8. One milliliter ofthis culture was mixed with 1 ml of a log-phase culture of plasmiddonor strain E. coli RM1259 and 1 ml of a log-phase culture ofhelper strain E. coli CA60 in a sterile 15-ml tube. The mixturewas filtered onto a 47-mm-diameter 0.2-µm-pore-size filter undera vacuum (~150 mm of Hg). After filtration, the filter was placedon an ASWJP nutrient plate, and incubated overnight at 28°C. Thefilter was then transferred to 5 ml of artificial seawater mediumin a sterile tube. Cells were washed off by vortexing the filterfor 30 s. The cell suspension was plated onto ASWJP nutrient platescontaining 250 µg of kanamycin per ml, 250 µg of streptomycinper ml, and 500 µg of rifampin per ml. The plates were incubatedat 28°C for at least 48 h. Colonies that grew on the selectionplates were picked, and we confirmed that they contained pQSR50by colony hybridization, plasmid preparation, and Southern hybridizationwith radiolabeled probe nptII (see below). The sensitivities ofthese plasmid-containing bacterial hosts to their correspondingphages were tested by phage typing. Strain HSIC containing plasmidpQSR50 was designated HOPE-1, and strain D1B containing plasmidpQSR50 was designated HOPE-2 (Table 1). Both strain HOPE-1 andstrain HOPE-2 were used as donors in the transduction assays.

Transduction assays. Strains HOPE-1 and HOPE-2 were used as plasmid donors, and transducing particles were produced by infecting these strainswith the corresponding temperature phages by the soft agar overlaymethod. The phages were eluted from the plates after overnightincubation by using warm 0.5 M Tris-HCl (pH 8.0). A second roundof phage lysate was produced with the same donor strain to ensurethat the transducing particles contained DNA only from the donors(28). The transducing lysates were filtered (pore size, 0.2µm) to remove residual donor cells. A subsample of the transducinglysate was treated with UV radiation (NIS G15T8 15-W germicidallamp; peak wavelength, 256 nm) to reduce the phage titer to 1%of the original titer (28). UV-treated and untreated phage lysateswere digested with 50 U of DNase I per ml before they were usedin the transduction assays to prevent transformation from occurring.

Both bacterial hosts isolated from Mamala Bay, Hawaii, and concentrated bacterial communities from Tampa Bay, Florida, theGulf of Mexico, and Dry Tortugas, Florida, were used as recipientsfor transduction. For cultured recipients, 10- to 100-ml portionsof log-phase cultures were mixed with transducing phage particlesat multiplicities of infection (MOI) ranging from 0.01 to 10.Each control contained an equal volume of the recipient cell cultureand 1 ml of 0.5 M Tris-HCl (pH 8.0). After a 10-min adsorptionperiod, the unabsorbed phages were removed by three rounds ofcentrifugation and three washes with artificial seawater. Thefinal washed cell pellet was resuspended in 0.5 to 1.5 ml of ASWJPnutrient broth, and the cells were allowed to recover (phenotypicexpression) in this nonselective medium for 10 to 20 min beforethey were plated onto selective seawater nutrient plates containing250 µg of kanamycin per ml and 250 µg of streptomycin per ml.The transducing phage lysate (containing no recipient) was alsoplated onto selective plates as a control.

For transduction assays in which indigenous marine bacterial communities were used as recipients, natural populations (in20 to 100 liters of water) from a variety of marine environmentswere concentrated to volumes of approximately 50 ml by vortexflow filtration by using a 100-kDa-cutoff filter (21). One milliliterof transducing phage lysate was added to 10 ml of a concentratedmicrobial population and incubated at room temperature for 10min to allow phage adsorption. The mixture was then filtered ontoa 47-mm-diameter 0.2-µm-pore-size filter. An equal volume of concentratedsample was used as a control. The filter was rinsed with sterileASWJP to wash off the unabsorbed phages and was transferred to2 ml of sterile ASWJP nutrient broth in a 15-ml tube. Bacteriaon the filter were resuspended in medium, and the suspension wasplated onto selective medium plates containing 500 µg of kanamycinper ml and 1,000 µg of streptomycin per ml. The phage lysate wasalso plated onto selective plates as a no-recipient control.

Purification of plasmid DNA and gene probe construction. Plasmid DNAs from the E. coli strains and from marine bacteria were purified by the alkaline lysis miniprep method (37)or with the Promega plasmid DNA purification system (Promega,Madison, Wis.).

A BamHI- and HindIII-digested fragment of the neomycin phosphotransferase gene (nptII) of plasmid pQSR50 was cloned into Riboprobevector pGEM 4Z (Promega) by using the manufacturer's recommendedprocedure. A detailed description of cloning and the locationof this fragment on the plasmid map have been published elsewhere(10). A ³⁵S-RNA probe was prepared by transcription of the fragment withT7 polymerase by using ³⁵S-UTP (12). This probe, designated the nptII probe on the basisof the complementary gene sequence in the plasmid (12), hybridizedwith the Tn5 region of the plasmid.

Fragments of T- $phi$ HSIC DNA and T- $phi$ D1B DNA were also cloned into a Riboprobe vector (Promega); ³⁵S-labeled single-stranded RNA probes, designated the T- $phi$ HSIC probeand the T- $phi$ D1B probe, respectively, were made as previously described(17).

Colony lift, dot blot, and Southern hybridization. Colonies grown on agar plates were lifted by using a Magna charged nylon transfer membrane (MSI, Westboro, Mass.) and werelysed by soaking them in 2× SSC (0.3 M NaCl plus 0.03 M sodiumcitrate, pH 7.0) containing 5% sodium dodecyl sulfate and microwavingthem for 2 min on gel blot paper (Schleicher & Schuell, Keene,N.H.). The lysed colonies were then denatured on gel blot papersaturated with 1.5 M NaOH and 1.5 M NaCl, and the pH was adjustedto 8.0 with 0.5 M Tris-HCl. DNA was fixed on the membrane by bakingthe membrane in a vacuum oven at 80°C for 2 h.

Plasmid DNA was dotted onto charged nylon membranes (Zetaprobe; Bio-Rad, Richmond, Calif.) by using a Bio-Rad Bio-Dot microfiltrationapparatus. The DNA on the membrane was denatured, neutralized,and fixed as previously described (22). Southern transfer ofDNA from agarose gels to charged nylon membranes (Zetaprobe; Bio-Rad)was performed by using the method of Sambrook et al. (37).

Hybridization of DNA with the nptII probe, T- $phi$ HSIC probe, or T- $phi$ D1B probe was performed at 42°C overnight. The wash temperaturewas 65°C, as previously described (17).

PCR amplification. When natural bacterial communities were used as recipients in the transduction assays, two sets of primers were employed inPCR amplification to detect the pQSR50 gene sequence and to differentiatethe putative transductants from the indigenous antibiotic-resistantcolonies. The primer locations and sequences are shown in Fig.1 and Table 2, respectively. Primers JP44 and JP52 were designedto amplify the Tn5 region of the plasmid, which is the regionthat codes for neomycin phosphotransferase. Primers JP64 and JP65were used to amplify the region near the EcoRI site, which isthe region farthest from the Tn5 insertion site (Fig. 1). Therationale for this procedure was to differentiate transpositionof Tn5 from maintenance of the rest of the plasmid.

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FIG. 1. Map of plasmid pQSR50, including the locations of PCR primers. Arrows indicate primer directions.

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TABLE 2. Oligonucleotides used as PCR primers

For amplification, the plasmid DNA was diluted 1 to 100 times with double-distilled deionized water. The PCR mixtures (totalvolume, 100 µl) contained 10 mM Tris, 50 mM MgCl₂, 0.01% gelatin,0.05% Nonidet P-40, each deoxynucleoside triphosphate at a concentrationof 37.5 µM, 20 pmol of each primer, approximately 1 ng of template,and 2.5 U of Taq DNA polymerase. The Taq DNA polymerase was pretreatedwith the TaqStart antibody (Clontech, Palo Alto, Calif.) to reduceamplification artifacts. The reaction mixture was overlaid with3 drops of sterile mineral oil. Sterile deionized water (DI) wasused as a template for a negative control. The PCR cycle includeda hot start (96°C, 5 min), 40 cycles consisting of 96°C for 45s, 58°C for 1 min, and 72°C for 1.5 min, and finally incubationat 72°C for 10 min. The amplification products were analyzed bygel electrophoresis.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Establishing indigenous marine phage-host transduction systems. To study the potential for gene transduction among marine phages and bacterial hosts, we attempted to establish transducingsystems by using marine phage host isolates. Four marine phage-hostsystems were isolated from Mamala Bay, Hawaii (17), and plasmidpQSR50 was successfully introduced into two of the bacterial hosts;the resulting strains were designated HOPE-1 and HOPE-2.

Strains HOPE-1 and HOPE-2 grew more slowly than the wild-type strains, possibly because of the burden of the new extrachromosomalelement. The plaquing efficiency of phage T- $phi$ D1B on strain HOPE-2was lower than the plaquing efficiency of this phage on its wild-typehost, D1B, because the titers of phage lysates collected afterinfection of HOPE-2 were often 10 to 100 times lower than thetiters of lysates generated from infection of strain D1B. Thesensitivity of strain HOPE-1 to the corresponding phage was basicallyunchanged, and strain HOPE-1 yielded approximately the same numberof viruses per infection cycle as when wild-type strain HSIC servedas the host.

Transduction assays performed with bacterial isolates as recipients. Both UV-treated and untreated transducing lysates were used in transduction assays. Transducing lysates of T- $phi$ HSIC were moreresistant to UV radiation, requiring 1 min of UV radiation at464 mW/cm² for a 2-log reduction in infectivity, while the infectivitiesof transducing lysates of T- $phi$ D1B were reduced by 2 logs after10 s of radiation.

Putative transductants were found in three experiments when HOPE-1 was used as the donor strain, UV-treated T- $phi$ HSIC was usedas the transducing lysate, and HSIC was used as the recipient(Table 3). Only transduction assays in which a low MOI (MOI,0.01 to 0.05) was used produced detectable transductants, eventhough MOIs of up to 5 were also tested (data not shown). Thefrequencies of transduction in lab trials ranged from 5.13 × 10⁹ to 1.33 × 10⁷ transductants per PFU or 4.02 × 10¹⁰ to 6.8 × 10¹⁰ transductants per CFU. The transduction frequencies when theuntreated HOPE-1-T- $phi$ HSIC and HOPE-2-T- $phi$ D1B systems were used werebelow the detection limit (see below).

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TABLE 3. Marine phage transduction with bacterial isolates as recipients

The putative transductants found on the selective plates coexisted with the phage. The colonies appeared to be wrinkled andto have colony morphology similar to that of the lysogen L-HSIC(17). Transductants were confirmed by probing the colony liftmembranes with the nptII probe. Strong hybridization of the nptIIprobe was found with E. coli RM1259, donor strain HOPE-1, andthe transductants (data not shown). No hybridization was observedin the wild-type recipients, which suggests that plasmid DNA wasintroduced into the recipients by phage transduction.

Analysis of plasmid DNA from transductants. To ensure that the transferred plasmid DNA was maintained as a plasmid in the transductants, plasmid DNAs extracted from E.coli RM1259, donor strains, recipient strains, and transductantswere dotted onto a nylon membrane and probed with the plasmidnptII probe (Fig. 2). Hybridization of the probe with DNAs fromE. coli RM1259, the donor strains, and all transductants was observedin the autoradiograph. No hybridization with the plasmid DNA fromrecipient strain HSIC was found. This result suggested that thetransferred plasmid DNA was maintained as an extrachromosomalelement in the transductant's cells.

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FIG. 2. Dot blot hybridization of plasmid DNAs from E. coli RM1259, donor strain HOPE-1, recipient strain HSIC, and transductants with the nptII probe.

The restriction patterns of the plasmid DNAs from transductants, donors, and recipients were analyzed to determine similaritiesand differences between the cells. Wild-type recipient strainHSIC contained a high-copy-number plasmid upon isolation, whichinterfered with the restriction pattern of the transduced plasmid(data not shown). Therefore, to determine the restriction patternsof the transduced plasmid, HindIII-digested and undigested plasmidDNAs from transductants, donors, recipients, and E. coli RM1259were Southern transferred to a nylon membrane and probed withradiolabeled nptII probe. Figure 3 shows the autoradiograph fromthe Southern hybridization experiment. The hybridization patternsof the digested and undigested transductant plasmid DNAs wereidentical to those of the donor plasmid DNA but were differentfrom those of pQSR50 DNA in E. coli RM1259. One large hybridizationband was missing from undigested pQSR50 in E. coli RM1259 (Fig.3, arrow). This change in the plasmid band pattern may have resultedfrom transposition of Tn5 from plasmid pQSR50 to an indigenousplasmid of the wild-type bacteria or from maintenance of the plasmidas a multimer in the new host. No hybridization with either uncutor HindIII-cut plasmid DNA of the recipient was observed.

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FIG. 3. Southern hybridization of undigested and HindIII-digested plasmid DNAs from transductants, E. coli RM1259, donor strain HOPE-1, and recipient strain HSIC, probed with the nptII probe. Lanes 1 through 20, plasmid DNAs from transductants; lanes 21 and 22, plasmid DNA from E. coli RM1259; lanes 23 and 24, plasmid DNA from donor strain HOPE-1; lanes 25 and 26, plasmid DNA from recipient strain HSIC. Odd-numbered lanes contained undigested plasmid DNA, whereas even-numbered lanes contained HindIII-digested DNA. Molecular weights (M) (in kilobases) are indicated on the left.

According to the plasmid pQSR50 gene map (Fig. 1) presented previously (10), HindIII digestion of this plasmid should generatea single 3.4-kb diagnostic band which hybridizes with the nptIIprobe. However, in all HindIII-digested plasmid DNAs, includingthe DNA of pQSR50 from parental strain RM1259, an unexpected 1.2-kbband was found to hybridize strongly with the probe. This Southernhybridization experiment was performed several times by usingplasmid DNA extracted by different methods, and the presence ofthis 1.2-kb band was confirmed. Although the reason for this bandis unknown, a similar hybridization pattern for HindIII-digestedpQSR50 was also seen by other workers (51).

A replicate Southern transfer of plasmid DNAs was probed with the T- $phi$ HSIC probe, and a 9-kb HindIII fragment was found tohybridize in all digests of transductant plasmid DNA (Fig. 4),while no hybridization was found in plasmid DNA from the donor,recipient, or E. coli RM1259. This result suggests that all ofthe transductants were lysogenized. However, whether transductionand lysogenization occurred simultaneously, with plasmid and phageDNAs entering each cell from a single transducing phage particle,or in a sequential process involving more than one phage is notknown. The sizes of the T- $phi$ HSIC genome and plasmid pQSR50 are37 and 14.4 kb, respectively. Therefore, it is possible for aphage particle to contain both plasmid DNA and part of the phagegenome. However, other possibilities are equally likely. To confirmlysogenization, all putative transductants were tested for sensitivityto T- $phi$ HSIC, and all were found to be resistant.

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FIG. 4. Southern hybridization of undigested (odd-numbered lanes) and HindIII-digested (even-numbered lanes) plasmid DNAs from transductants, E. coli RM1259, and donor and recipient strains probed with the T- $Phi$ HSIC riboprobe. For the contents of the lanes see the legend to Figure 3.

Transduction assays performed with indigenous bacterial communities as recipients. To understand the potential for transduction in the marine environment, concentrated bacterial communities from a varietyof marine environments were used as transduction recipients. Sixsamples were collected from Tampa Bay, Florida, the Gulf of Mexico,and Dry Tortugas, Florida, and indigenous bacteria from four ofthe sample sites were resistant to kanamycin and streptomycinand hybridized with the nptII probe before transduction, whichmade it impossible to detect transductants in these samples bythe currently used detection method. This may have been causedby Tn5-like sequences in the natural communities.

Potential transduction was found in two experiments (Table 4) performed with the bacterial recipients collected from themouth of Tampa Bay and the deep-sea environment of the Gulf ofMexico. The indigenous kanamycin- and streptomycin-resistant bacteriafrom these two locations did not hybridize with the nptII probebefore transducing phages were added (Fig. 5), but they were hybridizationpositive after transduction assays performed with the HOPE-2-T- $phi$ D1Btransducing lysate and the UV-treated HOPE-2-T- $phi$ D1B transducinglysate, respectively. The frequencies of transduction in thesebacterial communities ranged from 1.57 × 10⁸ to 3.7 × 10⁸ transductants/PFU (Table 4). No transduction was observed withT- $phi$ HSIC lysates.

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TABLE 4. Transduction performed with concentrated marine bacterial communities as recipients

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FIG. 5. Colony hybridization after a transduction assay performed with indigenous bacterial communities from Tampa Bay as recipients. (A) Control (no lysate added). (B) Transduction with HOPE-2-T- $phi$ D1b lysate. (C) Transduction with HOPE-1-T- $phi$ HSIC lysate. (D) Transduction with UV-treated HOPE-1- T- $phi$ HSIC lysate.

Plasmid miniprep analysis of these putative transductants yielded restriction patterns unlike the restriction patterns ofthe native pQSR50 plasmid (data not shown). Since we have observedsimilar phenomena after plasmid transformation of indigenous florarecently (12), we used PCR primers specific for pQSR50 to amplifythe plasmid DNA sequences from the control colonies (antibiotic-resistantindigenous recipients that did not hybridize with the plasmidprobe) and putative transductants. Figure 6 shows the resultsof amplification with primers JP44 and JP52, which specificallyamplify the Tn5 region of the pQSR50 plasmid. Amplification productswere observed only when the transductant plasmid and pQSR50 DNAswere used as templates (Fig. 6, lanes 1 through 7 and 13, respectively)and were hybridized with the nptII probe. Amplification productsor hybridization signals were not found when the plasmid DNAsof the control colonies were used.

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FIG. 6. Autoradiograph after Southern transfer of an agarose gel containing PCR products obtained with primers JP44 and JP52. The template DNAs were plasmid DNAs of transductants (lanes 1 through 7), plasmid DNAs of indigenous antibiotic-resistant bacteria (lanes 8 through 12), and pQSR50 DNA (lane 13). Lane 14 was a negative control (no template DNA). The preparations were hybridized with the nptII probe. Lane M contained a molecular weight marker; sizes (in base pairs) are indicated on the left.

Primers JP64 and JP65, designed to specifically amplify a 635-bp region of pQSR50 containing an EcoRI site (Fig. 1), werealso used to amplify the plasmid DNAs from the transductants andcontrol colonies. Amplification products that were approximately700 bp long were observed in the plasmid DNAs of the transductantsand pQSR50 (Fig. 7). However, the transductants' plasmid amplificationproducts were slightly larger than the pQSR50 amplification productand seemed to have lost the EcoRI site (Fig. 7). They were resistantto EcoRI digestion, while the amplification product of pQSR50was digested into two fragments (Fig. 7). Plasmid pQSR50 may haverecombined with an indigenous extrachromosomal element(s), andthe restriction site may have been lost during the process. Thepresence of similar gene sequences in the recipient cells mayhave also been a factor facilitating the transduction process(see below).

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FIG. 7. PCR amplification performed with primers JP64 and JP65 and EcoRI-digested amplification products. The template DNAs were DNAs from plasmids of transductants (lanes 1 through 10), indigenous antibiotic-resistant bacteria (lanes 11 and 12), and pQSR50 (lanes 13 and 14). Odd-numbered lanes contained uncut DNA, and even-numbered lanes contained EcoRI-cut DNA. Lane M contained a molecular weight ladder; sizes (in base pairs) are indicated on the right.

Primers JP64 and JP65 were also used to amplify plasmid DNAs from nptII hybridization-positive indigenous bacteria found inother environments. No amplification products were found in anyof the samples tested (data not shown). This result suggests thatthe indigenous bacteria were different from the putative transductants.Only putative transductants contained gene sequences similar tothe gene sequences in the region near the EcoRI restriction siteof the pQSR50 plasmid.

A gene probe constructed for the T- $phi$ D1B gene was used to probe the putative transductants from the environment. No hybridizationoccurred, suggesting that the transductants were not lysogenized(data not shown).

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

The results of transduction assays performed with indigenous marine phage host isolates and mixed bacterial communities asrecipients suggest that transduction can be a means of gene transferin the marine environment. In this study, we demonstrated thata marine phage host isolate is capable of transferring an antibiotic-resistantplasmid among bacterial hosts. Plasmid transduction in this phage-hostsystem was confirmed by selection of antibiotic-resistant colonieson nutrient plates, colony hybridization, plasmid DNA restrictionanalysis, and Southern hybridization. The potential for plasmidtransduction in marine bacterial communities was also assayedby using concentrated indigenous bacterial populations as recipients.Putative transductants were detected in two of the six experimentsperformed. These putative environmental transductants were separatedfrom indigenous antibiotic-resistant bacteria by colony hybridizationand PCR amplification with two sets of primers specific for tworegions of the plasmid. This was the first attempt to study thepotential for transduction in mixed marine bacterial communities.Ackermann and DuBow (1) have suggested that transduction canoccur in all phage-host systems because mistakes in phage replicationare made in all systems. However, the frequencies of transductionare often below the detection limit, or there is not a geneticmarker which can be detected.

The use of UV radiation-treated transducing lysates in this study may have increased the frequency of transduction. Many studieshave shown that UV treatment of transducing lysates increasesthe frequency of transduction from 10- to 50-fold (28). Theeffect of UV radiation may be due to inactivation of virulenteffects of the infectious bacteriophage particles that are presentin the lysate (7, 8). Alternatively, it has been suggestedthat this treatment stimulates recombination within a recipientcell, which leads to increased incorporation of the transducedDNA into the recipient's genetic elements (4). Sandri and Berger(38) showed that only about 10% of the P1 transducing DNA injectedinto a recipient cell was stably maintained in the cell. Recombinationwith the recipient native genetic elements could increase thestability of the introduced DNA. Therefore, the presence of genesequences similar to the gene sequence of the introduced DNA ina recipient cell may increase the transduction frequency via recombination.Such a similarity may facilitate plasmid transfer to natural communities.

Potential for gene transduction in the marine environment. Both viruses and bacteria are abundant and active in the marine environment. Recently, lysogenic bacteria have also been shownto be an important component of marine bacterial communities (18-20).It is reasonable to believe that transduction occurs in naturalmarine microbial populations. To predict the potential rate oftransduction in the marine environment, we constructed a simplemodel by using the following factors: bacterial abundance, viralabundance, and the frequencies of transduction. The results ofprevious transduction assays (23, 30, 36, 46) and thisstudy suggested that transduction frequency is a function of MOIand that this function is most similar to a second-order polynomialfunction (Y = aX² + bX + c), with the frequency of transduction decreasing belowand above the optimal MOI. Using transduction frequencies andMOI data presented in Table 4, we predicted a second-order polynomialequation by using Excel spreadsheet software (Microsoft Corp.).The relationship between transduction frequencies and MOI is expressedin a numerical model by equation 1:

Ft=−(2×10−8) M2+10−8 M+3×10−10 (1)

where F_t is the frequency of transduction and can be rewritten as the ratio of the number of transductants (T) to the numberof recipient bacteria (B) and M is the MOI, which is the ratioof phage concentration (P) to recipient bacterial concentration(B). Therefore, the numerical model for transduction (equation1) can be transformed to equations 2 and 3:

T/B=−(2×10−8) (P/B)2+(10−8) (P/B)+(3×10−10) (2)

T=−(2×10−8) P2/B+(10−8) P+(3×10−10) B (3)

Assuming that there are n types of phage-host systems in the marine environment and that all natural systems fit our modelof transduction based on the study of marine phage host isolates,then the total number of transductants (T_t) is sum of the numberof transductants in each phage-host system (T_i) and can be writtenas:

Tt=<LIM><OP>∑</OP><LL>i=1</LL><UL>n</UL></LIM> Ti (4)

Therefore, the total number of transductants in an aquatic system after extrapolation from equations 3 and 4 can be modeledby equation 5:

(5)

+<LIM><OP>∑</OP><LL>i=1</LL><UL>n</UL></LIM> (3×10−10)Bi

where

are the total number of viruses (P_t) and the total number of bacteria (B_t), respectively, in an environment. Therefore, equation5 can be rewritten:

Tt=−(2×10−8)Pt(Pi/Bi)+(10−8)Pt+(3×10−10)Bt (6)

In any microbial system, P_i ranges from 1 to a maximum of the total viral density. B_i ranges from the below the thresholddensity which supports viral replication to a maximum of the totalbacterial concentration. Wiggins and Alexander (50) suggestedthat the threshold density for bacterial hosts which supportsviral replication is about 10⁴ cells/ml in the aquatic environment. By using bacterial and viralconcentrations of 2 × 10⁹ cells/liter and 10¹⁰ virus particles/liter, respectively, for Tampa Bay, Florida (18),the total number of transductants in 1 liter of Tampa Bay waterper day was calculated from equation 6. The results ranged fromnegative values to 100 transductants/liter per day. Negative valuesresulted when the concentration of one type of phage was morethan 50% of its host concentration (P_i/B_i > 0.5), which is unlikelyin the environment. The maximum value resulted when the concentrationof the host population was maximum and the phage concentrationwas the lowest concentration observed. Assuming that negativevalues represent zero transductants, then from 0 to 100 transductantscan occur in 1 liter of water in 1 day in the Tampa Bay environment.When this transduction rate was extrapolated to the ecosystemscale of the Tampa Bay Estuary by using a bay water volume of3.56 × 10¹¹ liters, transduction rates of up to 1.3 × 10¹⁴ transductants per year were estimated.

This is the first attempt to quantify transduction rates in the marine environment, and our model is based on several assumptions.For example, the model assumes that all marine phages are infective.However, several researchers (45, 54) have suggested thata large number of phages in the environment are not infectiousbecause they are inactivated by solar radiation. Furthermore,we assumed that all phage-host systems in the marine environmentfit the transduction model generated with a single phage-hostsystem, which is unlikely. Other marine phage transduction systemsmay have generated different numerical models. In fact, highertransduction frequencies per MOI were detected previously in amarine Vibrio-phage transduction system (16). To simplify themodel, many factors which may influence the transduction ratewere not considered in the model, including temperature, ionicstrength, effect of predation on marine bacteria, and the nonspecificattachment of phage to other particles. To achieve a more closelyfitting transduction model for the marine environment, severalmarine phage-host transduction systems should be used to generatepolynomial empirical curves and equations, and all of the factorsmentioned above should be integrated into the model. However,despite the limitations of our current transduction model, thisquantitative estimation tool is important to our understandingof the potential for transduction in marine microbial systems.

In summary, this research demonstrated the potential for bacteriophage-mediated gene transfer in the marine environment. Genetransfer by transduction may be an important mechanism for geneevolution in the marine environment, and bacteriophage transductioncould play an important role in contributing to the genetic diversityof marine microbial populations.

	FOOTNOTES

^* Corresponding author. Mailing address: Marine Science Department, University of South Florida, St. Petersburg, FL 33701. Phone:(813) 553-1168. Fax: (813) 553-1189. E-mail: jpaul{at}seas.marine.usf.edu.

Present address: Center of Marine Biotechnology, University of Maryland Biotechnology Institute, Baltimore, MD 21202.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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1.	Ackermann, H. W., and M. S. DuBow. 1987. Viruses of prokaryotes, vol. 1. General properties of bacteriophages. CRC Press, Boca Raton, Fla.
2.	Bale, M. J., J. C. Fry, and M. J. Day. 1978. Plasmid transfer between strains of Pseudomonas aeruginosa on membrane filters attached to river stones. J. Gen. Microbiol. 133:3099-3107.
3.	Barsomina, G. D., N. J. Robillard, and C. B. Throne. 1984. Chromosomal mapping of Bacillus thuringiensis by transduction. J. Bacteriol. 157:746-750[Abstract/Free Full Text].
4.	Benzinger, T., and P. E. Hartmen. 1962. Effect of ultraviolet light on transducing phage P22. Virology 18:263-268.
5.	Bergh, O., K. Y. Borsheim, G. Bratbak, and M. Heldal. 1989. High abundance of viruses found in aquatic environments. Nature 340:467-468[Medline].
6.	Birge, E. A. 1994. Bacterial and bacteriophage genetics, 3rd ed. Springer-Verlag, New York, N.Y.
7.	Buchanan-Wollaston, V. 1979. Generalized transduction in Rhizobium leguminosarum. J. Gen. Microbiol. 112:135-142.
8.	Ely, B., and R. C. Johnson. 1977. Generalized transduction in Caulobacter crescentus. Genetics 87:391-399[Abstract/Free Full Text].
9.	Finan, T. M., E. Hartwieg, K. LeMieux, K. Bergman, G. C. Walker, and E. T. Signer. 1984. General transduction in Rhizobium meliloti. J. Bacteriol. 159:120-124[Abstract/Free Full Text].
10.	Frischer, M. E. 1994. Ph.D. dissertation. University of South Florida, St. Petersburg, Fla.
11.	Frischer, M. E., G. J. Gregory, and J. H. Paul. 1994. Plasmid transfer to indigenous marine bacterial populations by natural transformation. FEMS Microbiol. Ecol. 15:127-136.
12.	Frischer, M. E., J. M. Thurmond, and J. H. Paul. 1990. Natural plasmid transformation in a high-frequency-of-transformation marine Vibrio strain. Appl. Environ. Microbiol. 56:3439-3444[Abstract/Free Full Text].
13.	Frischer, M. E., J. M. Thurmond, and J. H. Paul. 1993. Factors affecting competence in a high frequency of transformation marine Vibrio. J. Gen. Microbiol. 139:753-761.
14.	Fuhrman, J. A., and C. A. Suttle. 1993. Viruses in marine planktonic systems. Oceanography 6:57-63.
15.	Gowland, P. C., and J. H. Slater. 1984. Transfer and stability of drug resistance plasmids in Escherichia coli K12. Microb. Ecol. 10:1-13.
16.	Ichige, A., S. Matsutani, K. Oishi, and S. Mizushima. 1989. Establishment of gene transfer systems and construction of the genetic map of a marine Vibrio strain. J. Bacteriol. 171:1825-1834[Abstract/Free Full Text].
17.	Jiang, S. C., C. A. Kellogg, and J. H. Paul. 1998. Characterization of marine temperate phage-host systems isolated from Mamala Bay, Hawaii. Appl. Environ. Microbiol. 64:535-542[Abstract/Free Full Text].
18.	Jiang, S. C., and J. H. Paul. 1994. Seasonal and diel abundance of viruses and occurrence of lysogeny/bacteriocinogeny in the marine environment. Mar. Ecol. Prog. Ser. 104:163-172.
19.	Jiang, S. C., and J. H. Paul. 1996. Occurrence of lysogenic bacteria in marine microbial communities as determined by prophage induction. Mar. Ecol. Prog. Ser. 142:27-38.
20.	Jiang, S. C., and J. H. Paul. 1998. Significance of lysogeny in the marine environment: studies with isolates and an ecosystem model. Microb. Ecol. 35:235-243[Medline].
21.	Jiang, S. C., J. M. Thurmond, S. L. Pichard, and J. H. Paul. 1992. Concentration of microbial populations from aquatic environments by vortex flow filtration. Mar. Ecol. Prog. Ser. 80:101-107.
22.	Kellogg, C. A., J. B. Rose, S. C. Jiang, J. M. Thurmond, and J. H. Paul. 1995. Genetic diversity of related vibriophages isolated from marine environments around Florida and Hawaii. Mar. Ecol. Prog. Ser. 120:89-98.
23.	Keynan, A., K. Nealson, H. Sideropoulos, and J. W. Hastins. 1974. Marine transducing bacteriophage attacking a luminous bacterium. J. Virol. 14:333-340[Abstract/Free Full Text].
24.	Levisohn, R., J. Moreland, and K. H. Nealson. 1987. Isolation and characterization of a generalized transducing phage for the marine luminous bacterium Vibrio fischeri MJ-1. J. Gen. Microbiol. 133:1577-1582.
25.	Martin, M. O., and S. R. Long. 1984. Generalized transduction in Rhizobium meliloti. J. Bacteriol. 159:125-129[Abstract/Free Full Text].
26.	McHenney, M. A., and R. H. Baltz. 1988. Transduction of plasmid DNA in Streptomyces spp. and related genera by bacteriophage FP43. J. Bacteriol. 170:2276-2282[Abstract/Free Full Text].
27.	Meyer, R., R. Laux, G. Boch, M. Hinds, R. Bayly, and J. A. Shapiro. 1982. Broad-host-range IncP-4 plasmid R1162: effects of deletions and insertions on plasmid maintenance and host range. J. Bacteriol. 152:140-150[Abstract/Free Full Text].
28.	Miller, R. V. 1992. Methods for evaluating transduction: an overview with environmental considerations. In M. A. Levin, R. J. Seidler, and M. Rogul (ed.), Microbial ecology. Principles, methods, and applications. McGraw-Hill, Inc., New York, N.Y.
29.	Miller, R. V., S. Ripp, J. Replicon, O. A. Ogunseitan, and T. A. Kokjohn. 1991. Virus-mediated gene transfer in freshwater environments, p. 51-62. In M. J. Gauthier (ed.), Gene transfers and environment. Proceedings of Third European Meeting on Bacterial Genetics and Ecology (BAGECO-3). Springer Verlag, Berlin, Germany.
30.	Morgan, A. F. 1979. Transduction of Pseudomonas aeruginosa with a mutant of bacteriophage E79. J. Bacteriol. 139:137-140[Abstract/Free Full Text].
31.	Morrison, W. D., R. V. Miller, and G. S. Sayler. 1978. Frequency of F116-mediated transduction of Pseudomonas aeruginosa in a freshwater environment. Appl. Environ. Microbiol. 36:724-730[Abstract/Free Full Text].
32.	O'Morchoe, S. B., O. Ogunseitan, G. S. Sayler, and R. V. Miller. 1988. Conjugal transfer of R68.45 and FP5 between Pseudomonas aeruginosa strains in a freshwater environment. Appl. Environ. Microbiol. 54:1923-1929[Abstract/Free Full Text].
33.	Paul, J. H., M. E. Frischer, and J. T. Thurmond. 1991. Gene transfer in marine water column and sediment microcosms by natural plasmid transformation. Appl. Environ. Microbiol. 57:718-724.
34.	Raya, R. R., and R. Klaenhammer. 1992. High-frequency plasmid transduction by Lactobacillus gasseri bacteriophage $phi$ adh. Appl. Environ. Microbiol. 58:187-193[Abstract/Free Full Text].
35.	Ripp, S., and R. V. Miller. 1995. Effects of suspended particulates on the frequency of transduction among Pseudomonas aeruginosa in a freshwater environment. Appl. Environ. Microbiol. 61:1214-1219[Abstract].
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