Bacteriophage Therapy To Reduce Salmonella Colonization of Broiler Chickens

Acute enteric infections caused by salmonellas remain a majorpublic health burden worldwide. Poultry, particularly chickens,are known to be the main reservoir for this zoonotic pathogen.Although some progress has been made in reducing Salmonellacolonization of broiler chickens by using biosecurity and antimicrobials,it still remains a considerable problem. The use of host-specificbacteriophages as a biocontrol is one possible interventionby which Salmonella colonization could be reduced. A total of232 Salmonella bacteriophages were isolated from poultry farms,abattoirs, and wastewater in 2004 and 2005. Three phages exhibitingthe broadest host ranges against Salmonella enterica serotypesEnteritidis, Hadar, and Typhimurium were characterized furtherby determining their morphology and lytic activity in vitro.These phages were then administered in antacid suspension tobirds experimentally colonized with specific Salmonella hoststrains. The first phage reduced S. enterica serotype Enteritidiscecal colonization by $≥$ 4.2 log₁₀ CFU within 24 h compared withcontrols. Administration of the second phage reduced S. entericaserotype Typhimurium by $≥$ 2.19 log₁₀ CFU within 24 h. The thirdbacteriophage was ineffective at reducing S. enterica serotypeHadar colonization. Bacteriophage resistance occurred at a frequencycommensurate with the titer of phage being administered, withlarger phage titers resulting in a greater proportion of resistantsalmonellas. The selection of appropriate bacteriophages andoptimization of both the timing and method of phage deliveryare key factors in the successful phage-mediated control ofsalmonellas in broiler chickens.

INTRODUCTION

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INTRODUCTION

Salmonella continues to be a major public health burden worldwide(http://www.who.int/mediacenter/factsheets/fs139/en/). Morethan 35,000 cases of human salmonellosis were reported in theUnited States in 2004 alone (6), and more than 192,000 caseswere reported in the European Union during the same period (13).The annual cost of medical treatment for salmonellosis, in additionto lost productivity, imposes a considerable financial burdenon many countries. The USDA estimated this cost at more than$2.3 billion for the United States in 2005 (http://www.ers.usda.gov/briefing/FoodborneDisease/features.htm).Contaminated poultry products are widely accepted as a majorsource of Salmonella infections (7). However, controlling Salmonellain poultry is problematic and for broiler chickens this hasrelied historically on a combination of farm biosecurity andthe use of antibiotics (11). Concerns regarding the use of chemicaladditives in food production have led the European Union toban many of the antibiotics and growth promoters used in therearing of broiler chickens. These include spiramycin and tylosinphosphate, which were banned in 1999 (4). In the United States,the FDA has taken similar steps with the recent withdrawal ofenrofloxacin for use in poultry production (http://www.fda.gov/oc/antimicrobial/baytril.pdf).Banning or significantly reducing agricultural antibiotic usagemay reduce produce quality, yields, and microbiological safety(26). Likewise, constraints on chemical treatments such as chlorinein the abattoir may increase the risk of contamination withbacterial pathogens. Further, significant improvements in biosecurityon poultry farms are likely to be very expensive and difficultto maintain (11), so there is a need to find an acceptable,cost-effective way of preventing infection of poultry with Salmonella(2). Bacteriophage therapy is one possible method of achievingthis goal which has gained prominence in recent years (25, 27).Bacteriophages (phages) are natural predators of bacteria andare ubiquitous in the environment (21). The use of host-specificbacteriophages has been promoted as a cost-effective and adaptableapproach to control zoonotic bacteria (26). Phages have uniqueadvantages compared with antibiotics (17). They replicate onlyon the targeted subset of bacteria, avoiding the imbalance ofcommensal gut flora (dysbiosis) often caused by broad-spectrumantibiotics. Additionally, they only replicate as long as thetargeted bacterium is present and so are naturally self-limiting(8). Phages have been used against zoonotic pathogens in liveanimals and on food surfaces in previous studies (3, 5, 24).Bacteriophages have been used to reduce the numbers of Campylobacterjejuni bacteria in commercial broilers by up to 5.0 log₁₀ CFUg^–1 cecal content (18). However, only modest reductionsof up to 1.3 log₁₀ CFU have been recorded for similar studieswith Salmonella enterica serotype Enteritidis (23). Both Campylobacterand Salmonella phages can be isolated readily from poultry excretaand the poultry farm environment (9, 12, 14) and therefore wouldnot introduce any new biological entity into the food chainif used therapeutically. The emergence of bacteriophage-insensitivemutants (BIMs) has long been perceived as a major limitationof phage therapy (8). However, unlike chemotherapeutic agentssuch as antibiotics, phages constantly evolve to circumventtheir host's defenses and resistant bacteria are often lessfit or less virulent than their phage-sensitive counterparts(24). Here we describe the use of Salmonella phages to reducethe numbers of different Salmonella serotypes colonizing thececa of commercial broiler chickens. We also describe the invitro experiments used to characterize and select suitable phagetherapy candidates. Finally, we report the incidence of phageresistance in vivo and the implications of this for Salmonellaphage therapy in broiler chickens.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Isolation of bacteriophage from environmental samples.
Samples of poultry excreta and effluent were taken from 26 farms,poultry-processing plants, and wastewater treatment plants insouthern England during 2004 and 2005. These environmental sampleswere diluted 1:9 (wt/vol) in nutrient broth (NB, CM0001; Oxoid,Basingstoke, United Kingdom) before the addition of 8.0 log₁₀CFU of each of three Salmonella Nal^r host strains (S. entericaserotypes Enteritidis P125109, Hadar 18, and Typhimurium 4/74)and incubation at 37°C for 24 h. Following enrichment, a1-ml sample of each culture was subjected to centrifugationat 13,000 x g for 5 min. The supernatant was then filtered througha 0.45-µm-pore-size membrane (16533K; Sartorius, Göttingen,Germany) before 20-µl volumes of filtrate were spottedonto the surfaces of Salmonella lawns prepared by a modificationof the method described by Sambrook and colleagues (22). Briefly,this consisted of adding 0.1 ml of an 8.0-log₁₀-CFU-ml ^–1suspension of Salmonella in maximum-recovery diluent (MRD, CM0733;Oxoid) to 5 ml of molten overlay agar (NB containing 0.5% [wt/vol]bacteriological agar LP0011 [Oxoid]), gently shaking the mixture,and adding it to prewarmed (37°C, 30 min) nutrient agar(CM0003; Oxoid) plates containing 25 µg ml sodium nalidixate^–1(N4382; Sigma, Dorset, United Kingdom) and 1 µg ml novobiocin^–1(N1268; Sigma). The plates were incubated at 37°C for 24h before examination for plaques. Individual plaques were extractedfrom the overlay agar with a pipette and suspended in 100 µlof SM buffer (50 mM Tris-Cl [pH 7.5], 0.1 M NaCl, 8 mM MgSO₄· 7H₂O, 0.01% gelatin, reagents from Sigma). This suspensionwas incubated for 15 min at 37°C with 100 µl of an8.0-log₁₀ suspension of Salmonella before addition to 5 ml ofmolten overlay agar and pouring onto a nutrient agar plate.These plates were incubated as described above and examinedfor plaques after 24 h. Single plaques were propagated in thisway a total of three times to ensure that the isolates representeda single clone.

Enumeration of salmonellas in cecal contents.
A suspension of cecal contents (1:9, wt/vol) was prepared inMRD and then decimally diluted in the same medium down to 10^–4.A 100-µl volume of each dilution was spread plated ontomodified brilliant green (BG) agar, (CM0329; Oxoid) containing25 µg ml sodium nalidixate^–1 and 1 µg ml novobiocin^–1.The plates were incubated at 37°C for 24 h before typicalSalmonella colonies were counted. Representative Salmonellacolonies were confirmed by slide agglutination tests with poly(O)-,poly(H)-, and serotype-specific antisera (Pro-Lab Diagnostics,Cheshire, United Kingdom).

Bacteriophage enumeration in cecal contents.
A suspension of cecal contents (1:9, wt/vol) was prepared inSM buffer and subjected to centrifugation at 13,000 x g for5 min to remove bulk debris. The supernatant was then filteredthrough a 0.45-µm-pore-size filter to remove any remainingbacteria. Decimal dilutions of this filtrate were prepared inSM buffer down to 10^–4 and subsequently spotted (20 µl)onto lawns of the appropriate Salmonella host as described above.

Host range determination.
The host range of each bacteriophage isolate was determinedwith 70 Salmonella isolates. The Salmonella serotypes and strainsused were Enteritidis PT4 (n = 15), Enteritidis UT (n = 4),Enteritidis PT21B (n = 2), Enteritidis PT1B, 4,12:d:–(n = 7), Enteritidis UT (n = 6), Typhimurium PT36 (n = 2), TyphimuriumPT208, Typhimurium F98, Binza (n = 5), 3,15:y:– (n = 3),Virchow (n = 2), Typhi, Stanley, Ohio, Kisarowe, Hadar PT2,Togba, Barielly, Munster/Orion, Infantis, Senftenburg, Montevideo,Kattburg, Saint Paul, Kubacha, Amsterdam, Hadar 18, Java, Derby,Braenderup, Agama, and Amina. Bacterial lysis was determinedby spotting 20 µl of a 7.0-log₁₀-PFU-ml^–1 suspensionof phage onto lawns of Salmonella prepared as described above.After allowing 20 min for the spots to be absorbed, the plateswere inverted and incubated for 24 h at 37°C before thedegree of lysis was recorded.

Phage replication in vitro.
A 20-ml volume of NB, prewarmed at 37°C, was inoculatedwith 100 µl of an overnight culture of Salmonella (approximately10⁹ CFU ml^–1). The inoculated broth was then incubatedstatically for 4 h at 37°C. Following incubation, aliquots(200 µl) of this broth were inoculated with dilutionsof phage suspension to give multiplicities of infection (MOIs)of approximately 10°, 10³, and 10⁶. Three replicate aliquotsof each MOI, along with Salmonella-only controls, were thentransferred to the wells of a honeycomb microtiter plate. Theseplates were incubated at 37°C in a Bioscreen-C automatedmicrobiology growth curve analysis system (Labsystems Corp.,Finland). The optical density (600 nm) of each well was recordedat 30-min intervals for 24 h. Duplicate samples of each MOIand control were used for the contemporaneous enumeration ofSalmonella bacteria and phages in the suspension at 1-h intervalsfor 10 h and again at 24 h. For enumeration of salmonellas,decimal dilutions of each suspension were spread plated (100µl) onto BG agar in triplicate and incubated at 37°Cfor 24 h before examination for Salmonella colonies. For bacteriophageenumeration, a 1-ml aliquot of each suspension was subjectedto centrifugation at 13,000 x g for 5 min. The supernatant wasthen filtered through a 0.45-µm-pore-size filter to removeany remaining bacteria. Decimal dilutions of this filtrate wereprepared in SM buffer and subsequently spotted (20 µl)onto lawns of the appropriate Salmonella host as described above.

Examination of phage morphology (electron microscopy).
Eight microliters of an 8.0-log₁₀-PFU-ml^–1 suspensionof phage was added to the surface of a glow-discharged, carbon-coatedPioloform grid and fixed for 2 min with glutaraldehyde vapor.Excess sample was removed, and the grid was washed with a dropof double-distilled water. Negative staining was performed byadding 1 drop of 0.5% uranyl acetate to the grid surface, andexcess stain was removed immediately. The grids were allowedto air dry for 20 min and were then observed with a JEOL 1220transmission electron microscope. Digital images from the microscopewere captured with a SIS Megaview III camera.

Experimental birds.
Salmonella-free Ross broiler chickens were obtained at 34 daysof age from a commercial supplier (Lloyd Maunder, Devon, UnitedKingdom). The birds were housed in groups of three in floorboxes in a controlled environment under strict conditions ofbiosecurity. To ensure that the experimental birds remainedfree of naturally occurring infection, fecal samples were takeneach day and tested for Salmonella by enrichment in modifiedRappaport-Vassiliadis soya peptone broth (CM0669; Oxoid) andthen streaking onto BG agar. Fecal samples were also taken todetermine if any preexisting Salmonella phages were presentby using the enrichment method described for the environmentalsamples. Following infection, the birds were sacrificed at intervalsand the ceca were aseptically removed. The contents of the lumenwere collected in sterile universal tubes for Salmonella andphage enumeration. Salmonella colonization of the livers ofthe birds was ascertained by inserting a swab into the liverand using this to inoculate a BG agar plate for a semiquantitativecount. The swab was then enriched for Salmonella in modifiedRappaport-Vassiliadis soya peptone broth, followed by platingonto BG agar as described above.

Bacteriophage therapy trials.
Broiler chickens (n = 216 for trial 1 and 108 for trial 2) wereseparated at random into one of three units. Each unit was usedfor one of three Salmonella strains: Enteritidis P125109, Hadar18, or Typhimurium 4/74. The birds in each unit were separatedequally into four rooms (A, B, C, or D) and housed in groupsof three in floor boxes. The birds in each room were treatedas follows: the birds in room A were all inoculated with Salmonellaonly; in room B, the birds were inoculated with phage only;and in rooms C and D, the birds received both Salmonella andphage. All Salmonella and bacteriophage suspensions were administeredby oral gavage. At 36 days of age, the birds in rooms A, C,and D were challenged with 1 ml of an 8.0-log₁₀-CFU-ml^–1suspension of Nal^r Salmonella in phosphate-buffered saline (PBS,BR0014; Oxoid); the birds in room B were inoculated with 1 mlof PBS. At 38 days of age, the birds in groups B, C, and D wereinoculated with either 1 ml of 9.0 (trial 1) or 11.0 (trial2) log₁₀ PFU of bacteriophage ${phi}$ 151 (S. enterica serotype EnteritidisP125109), ${phi}$ 25 (S. enterica serotype Hadar 18), or ${phi}$ 10 (S. entericaserotype Typhimurium 4/74) in PBS containing 30% (wt/vol) CaCO₃as an antacid. At the same time, the birds in group A were inoculatedwith 1 ml of PBS containing 30% (wt/vol) CaCO₃. Three animalsfrom each room were sacrificed daily following phage treatmentfor up to 6 days (trial 1) or 3 days (trial 2). The cecum wasaseptically removed from each bird, and the contents were decimallydiluted in MRD or SM buffer for the enumeration of salmonellasand phages, respectively.

Statistical treatment of data.
The significance of differences between control and phage-treatedexperimental groups was determined on log₁₀-transformed databy a single-factor analysis of variance (ANOVA; Microsoft Excel2002). The significance of increased phage resistance in Salmonellacolonies isolated from phage-treated birds was determined bythe chi-square test (SPSS 14.0 for Microsoft Windows).

RESULTS

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RESULTS

Isolation and characterization of phages.
A total of 232 Salmonella phages were isolated from 26 samplingsites (broiler farms, poultry abattoirs, and wastewater plants)during 2004 and 2005. Following three rounds of serial plaquepurification, the host range of each phage was determined against70 Salmonella isolates representing 24 different serotypes (aportion of this screening is shown in Table 1). The 232 phageisolates could be ascribed to more than 80 lytic profiles. However,when differences between the lytic spectra of bacteriophageare small, further characterization is required to ensure thatthe phage isolates are not identical. On the basis of the lytic-spectrumdata, three phages with the broadest host range against S. entericaserotypes Enteritidis ( ${phi}$ 151), Hadar ( ${phi}$ 25), and Typhimurium ( ${phi}$ 10)were selected for further characterization. Examination of thephage suspensions by electron microscopy revealed that S. entericaserotype Enteritidis phage ${phi}$ 151 belongs to the Myoviridae familyof double-stranded DNA phages. S. enterica serotype Hadar phage ${phi}$ 25 and S. enterica serotype Typhimurium phage ${phi}$ 10 belong to theSiphoviridae family of double-stranded DNA phages. Representativeelectron micrographs of these phages are presented in Fig. 1.

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TABLE 1. Lytic spectra of 10 Salmonella bacteriophage isolates determined on 41 Salmonella host strains^a

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FIG. 1. Electron photomicrographs of Salmonella phages ${phi}$ 10 (A), ${phi}$ 25 (B), and ${phi}$ 151 (C). Phages ${phi}$ 10 and ${phi}$ 25 both exhibit icosahedral heads and flexible tails typical of members of the Siphoviridae family. With its icosahedral head and contractile tail, phage ${phi}$ 151 typifies members of the Myoviridae family. The bars represent 250 nm.

Replication dynamics of phage in vitro.
The replication dynamics of each candidate phage were determinedin vitro at MOIs of 10°, 10³, and 10⁶ prior to applicationin vivo. Both the optical density and plate count data indicatedthat the number of bacteria of each Salmonella serotype wasreduced appreciably in the presence of phage at each MOI after24 h (Fig. 2). When the highest MOI was used, S. enterica serotypeEnteritidis P12509, Hadar 18, and Typhimurium 4/74 numbers werereduced by means of 2.2, 2.5, and 5.9 log₁₀ CFU ml^–1,respectively, after 24 h compared with the controls. These reductionswere significant by a single-factor ANOVA (P < 0.00001).The scale and duration of Salmonella reduction varied accordingto the MOI used, with higher ratios of phage to bacteria resultingin the greatest initial falls ( $≤$ 10 h following infection). However,the differences between MOI groups generally became less pronouncedduring the 24-h incubation period (Fig. 2).

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FIG. 2. Graphs A1, B1, and C1 show the optical density readings (at 600 nm) of NB cultures of S. enterica serotypes Enteritidis P125109, Hadar 18, and Typhimurium 4/74, respectively, over a 24-h period. Phages ${phi}$ 151, ${phi}$ 25, and ${phi}$ 10 were separately added to exponential growth phase cultures of S. enterica serotypes Enteritidis, Hadar, and Typhimurium, respectively, at MOIs of 10° ( ${circ}$ ), 10³ ( ${square}$ ), and 10⁶ ( ${diamond}$ ). Optical density readings taken from uninfected cultures are also shown (•). Graphs A2, B2, and C2 show the plate counts of bacteriophages ( ${blacksquare}$ ) and uninfected (•) and infected ( ${diamond}$ ) Salmonella cultures recorded from the same samples (only data for the highest MOIs are presented). All means and standard deviations were calculated by using data from six replicates (optical density) or plate counts (culture) per MOI.

In vivo trials.
Phages ${phi}$ 151, ${phi}$ 25, and ${phi}$ 10 were used at a lower titer (9.0 log₁₀PFU ml^–1, trial 1) and a higher titer (11.0 log₁₀ PFUml^–1, trial 2) in separate in vivo trials to reduce thenumbers of Nal^r S. enterica serotype Enteritidis P125109, Hadar18, and Typhimurium 4/74 bacteria colonizing the ceca of broilerchickens. When the phages were administered at 9.0 log₁₀ PFU,no significant reductions in the cecal carriage of Salmonellain the phage-treated broilers was recorded for any of the serotypestested over the 6-day duration of the trial. This was despitea significant increase in the titers of phage ${phi}$ 151 (5.2 ±1.63 log₁₀ PFU g^–1 cecal content compared with controls)within 24 h of phage administration (data not shown). The phageswere rapidly removed from the chicken intestine in the absenceof Salmonella hosts (group B) and were below the limit of detectionafter 48 h ( ${phi}$ 151) or 72 h ( ${phi}$ 10, ${phi}$ 25). In the second trial, thechickens were sacrificed over a period of 3 days only, as theresults from trial 1 indicated that any decrease in Salmonellanumbers following phage treatment should be apparent in thisperiod (data not shown). The results of this second trial arepresented in Fig. 3. The higher phage titer corresponded toa significant reduction in the mean cecal colonization by S.enterica serotypes Enteritidis P125109 and Typhimurium 4/74after 24 h (1.53 ± 2.38 and 3.48 ± 1.88 log₁₀CFU g^–1 cecal content, respectively, compared with thecontrol groups [5.77 ± 1.85 and 5.67 ± 0.41 log₁₀CFU g^–1 cecal content]). These reductions in cecal colonizationwere significant for both S. enterica serotypes Enteritidis(P < 0.0000001) and Typhimurium (P < 0.000001) by a single-factorANOVA. No significant differences between control and phage-treatedgroups were recorded for birds colonized with S. enterica serotypeHadar 18 (5.77 ± 0.45 and 5.34 ± 0.34 log₁₀ CFUg^–1 cecal content for phage-treated and control groups,respectively).

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FIG. 3. Efficacy of high-titer phage treatment in reducing Salmonella counts in the ceca of broiler chickens (trial 2). Broiler chickens colonized by S. enterica serotype Enteritidis P125109 (A), Hadar 18 (B), or Typhimurium 4/74 (C) were treated separately with 11.0 log₁₀ PFU of phage ${phi}$ 151, ${phi}$ 25, or ${phi}$ 10, respectively. Salmonella counts from the ceca of individual control birds ( ${blacksquare}$ ) and phage-treated birds ( ${square}$ ) are presented as log₁₀ CFU g^–1 cecal content.

Resistance to phage in vivo.
Following the phage therapy trials, up to six Salmonella colonieswere randomly selected from spread plates from the cecal contentsof control and phage-treated birds. These colonies were usedto prepare lawns onto which phage suspensions were spotted inorder to determine the presence of BIMs. A total of 595 colonieswere tested in this way (271 for trial 1 and 324 for trial 2).For both trial 1 and trial 2, salmonellas recovered from controlanimals harbored a subpopulation which was naturally resistantto the phage chosen for therapy. Over the course of trial 1,the number of phage-resistant Salmonella colonies from controlanimals was 3/24 (12.5%) for S. enterica serotype Enteritidis,3/23 (13%) for S. enterica serotype Hadar, and 3/44 (6.8%) forS. enterica serotype Typhimurium. Corresponding values for trial2 were 11/37 (29.7%) for S. enterica serotype Enteritidis, 3/36(8.3%) for S. enterica serotype Hadar, and 1/52 (1.9%) for S.enterica serotype Typhimurium. Following phage treatment intrial 1, the percentage of BIMs approximately doubled (S. entericaserotype Enteritidis, 11/52 [21.2%]; S. enterica serotype Hadar,9/39 [23%]; S. enterica serotype Typhimurium, 9/89 [10%]). Thepercentage of BIMs recovered from phage-treated birds in trial2 was greater than that in trial 1 for S. enterica serotypesEnteritidis (65/74, 87.8%) and Typhimurium (52/62, 83.9%) butnot for serotype Hadar (5/63, 7.93%). The increase in BIMs recoveredfrom phage-treated birds harboring S. enterica serotypes Enteritidisand Typhimurium in trial 2 was significant for both groups (P< 0.001) by the chi-square test. Salmonella colonies recoveredfrom phage-treated birds (n = 20) did not maintain their phage-resistantphenotype when subcultured on BG agar five times. A small-scaletrial was performed to establish if phage resistance was maintainedin vivo. Three Salmonella BIMs (S. enterica serotypes EnteritidisR₁, Hadar R₂, and Typhimurium R₃) were selected for each serotypefrom trial 1 and used to reinfect a small group of birds (n= 9) as described above. After 6 days, the birds were sacrificedand the cecal contents were cultured for salmonellas and phageas described above. Colonization levels in the ceca for eachresistant Salmonella did not differ appreciably from the controls(data not shown). Additionally, when six colonies from eachbird were subsequently screened for phage resistance, the proportionof BIMs did not differ appreciably from the controls.

DISCUSSION

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DISCUSSION

Bacteriophage therapy is undergoing a renaissance in industrializedcountries (1). An increasing number of studies have examinedthe use of phage against food spoilage bacteria or zoonoticpathogens (15, 16). However, for phage therapy to be usefulin agricultural applications, it must be tested under conditionswhich emulate commercial practices. We sought to isolate anduse phage to reduce the numbers of three Salmonella serotypesin commercially obtained animals under conditions more congruouswith the broiler farm environment. Using specific-pathogen-freeanimals or applying phage in chick models of Salmonella colonizationmay produce misleading results as Salmonella colonizes theseanimals more readily than older birds (10). Applying phage justprior to slaughter is more likely to result in greater efficacyand a reduced proportion of BIMs (8).

Before the three phages were used against Salmonella in vivo,the replication dynamics of each phage-host system were characterizedin vitro. Each phage was able to significantly reduce the numbersof their respective Salmonella hosts with MOIs of 10°, 10³,and 10⁶. In the case of ${phi}$ 10 applied at an MOI of 10⁶, S. entericaserotype Typhimurium counts were reduced to below the limitof detection over a 24-h period.

It was envisaged that phage treatment would be most efficaciousfor Salmonella close to the slaughter age of commercially rearedbroiler chickens (approximately 40 to 42 days in the UnitedKingdom). Therefore, the efficacy of phage therapy would bemaximized by the use of a high titer of bacteriophage to reduceSalmonella colonization by passive inundation (19, 20). In thefirst trial, the birds were inoculated with 9.0 log₁₀ PFU ofphage. This should have resulted in an approximate MOI of 10⁶,which was found to be highly effective in vitro. However, cecalcounts of the three Salmonella serotypes were not reduced significantlyfollowing phage treatment. The dynamics of phage-bacterium interactionsin vivo may be very different from those in vitro because ofthe viscosity of the gut matrix (29), complex physicochemicalenvironment, and host defenses (8). The numbers of salmonellasin the ceca of commercial broiler chickens and on processedcarcasses are generally low (10, 28). This compounds the problemsphage have in locating a suitable host in a complex intestinalmilieu containing large numbers of "decoy" bacteria and particulatematter. The influence of these decoys may be negligible whenthe number of target bacteria is high, for example, with Campylobacter( $~$ 7.0 log₁₀ CFU g^–1 cecal content). However, as the ratioof target-to-decoy bacteria decreases, the number of phage requiredto achieve a significant reduction in host numbers increases.Indeed, if the number of target bacteria falls below a minimumnumber, termed the phage proliferation threshold (19, 30), thelarge number of phage required may render phage therapy impractical.

In order to assess whether a higher phage MOI would be moreeffective, a second in vivo trial was performed with 11.0 log₁₀PFU. It was clear from the second trial that increasing theMOI by 100-fold overcame many of the problems of the low numberof host bacteria present in the ceca. On the first day afterphage treatment, S. enterica serotype Enteritidis bacterialnumbers were reduced significantly by 2.52 log₁₀ CFU g^–1.By day 2, the S. enterica serotype Enteritidis count in thephage-treated birds was 1.53 ± 2.38 log₁₀ CFU, comparedwith 5.77 ± 1.85 log₁₀ CFU in control birds. A significantreduction in S. enterica serotype Typhimurium counts was alsorecorded for phage-treated birds on day 2 (mean of 3.48 ±1.88, compared with 5.67 ± 0.41 log₁₀ CFU g^–1 forcontrols). However, no significant reductions in S. entericaserotype Hadar counts were recorded in either trial 1 or trial2. This was surprising in view of the results obtained for theother serotypes in trial 2 and the activity recorded for ${phi}$ 25in vitro. The proportion of S. enterica serotype Hadar BIMsrecovered from phage-treated birds remained low compared withthe other two serotypes (7.9%, compared with 87.8% for S. entericaserotype Enteritidis and 83.9% for S. enterica serotype Typhimurium).If phage therapy relies mainly on passive inundation ratherthan successive rounds of viral infection and replication, significantnumbers of phage are needed to adsorb to individual host cells.S. enterica serotype Hadar 18 may not possess a sufficient numberof accessible receptors on the cell surface to allow the adsorptionof large numbers of phage. Loss or alteration of the phage receptor(s)or restriction modification systems is unlikely to explain why ${phi}$ 25 was ineffective, as this would have been detected duringthe in vitro experiments. Nevertheless, it is clear that thebehavior of ${phi}$ 25 in vitro was not a reliable indication of itsactivity in vivo. Identifying the receptor(s) for ${phi}$ 25 may allowmore precise bacteriophage therapy through the use of cocktailsof phages which adsorb to different receptors. This may alsoneed to be the case for phages which infect S. enterica serotypesEnteritidis and Typhimurium in order to delay the successionof phage-resistant mutants.

This study has demonstrated that bacteriophages can be usedto significantly reduce the cecal colonization of S. entericaserotypes Enteritidis and Typhimurium in commercial broilerchickens. Although BIMs were able to colonize chicken ceca within24 to 48 h of phage treatment, phage resistance was not maintainedfor long periods either in vitro or in vivo. The results ofthis study are promising, although further work needs to beundertaken to determine the optimal timing and delivery of bacteriophagein a real-life poultry industry setting.

ACKNOWLEDGMENTS

This work was funded by EU FP6 project SUPASALVAC.

We thank Ann Cornish, Pauline Hunt, Charlie Chambers, MariaRubio, Danilo Hernandez, Tristan Cogan, and Helen Weaver forassistance. We thank Wendy Fielder and Christine Dodd (Universityof Nottingham) for providing several of the Salmonella strainsused in this study. We thank Stefan Hyman and Natalie Allcock(University of Leicester) for expert assistance in electronmicroscopy.

FOOTNOTES

* Corresponding author. Mailing address: Department of Clinical Veterinary Science, University of Bristol, Langford, Bristol BS40 5DU, United Kingdom. Phone: 44 (0)117 331 9016. Fax: 44 (0)117 928 9324. E-mail: Robert.Atterbury{at}bristol.ac.uk

Published ahead of print on 25 May 2007.

R.J.A. and M.A.P.V.B. contributed equally to this work.

REFERENCES

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