Influence of genotype and diet on steer performance, manure odor, and carriage of pathogenic and other fecal bacteria. II. Pathogenic and other fecal bacteria

doi:10.2527/jas.2005-747

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Influence of genotype and diet on steer performance, manure odor, and carriage of pathogenic and other fecal bacteria. II. Pathogenic and other fecal bacteria¹^,2

E. D. Berry³, J. E. Wells, S. L. Archibeque, C. L. Ferrell, H. C. Freetly and D. N. Miller⁴

USDA-ARS, US Meat Animal Research Center, Clay Center, NE 68933

Abstract

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Abstract
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
LITERATURE CITED

This study assessed the influence of cattle genotype and dieton the carriage and shedding of zoonotic bacterial pathogensand levels of generic Escherichia coli in feces and ruminalcontents of beef cattle during the growing and finishing periods.Fifty-one steers of varying proportions of Brahman and MARCIII [0 (15), $1/4$ (20), $1/2$ (7), and $3/4$ Brahman (9)] genotypes were dividedamong 8 pens, such that each breed type was represented in eachpen. Four pens each were assigned to 1 of 2 diets [100% choppedbromegrass hay or a diet composed primarily of corn silage (87%)]that were individually fed for a 119-d growing period, at whichtime the steers were switched to the same high-concentrate,corn-based finishing diet and fed to a target weight of 560kg. Feces or ruminal fluid were collected and analyzed at alternatingintervals of 14 d or less. Generic E. coli concentrations infeces or ruminal fluid did not differ (P > 0.10) by genotypeor by growing diet in the growing or finishing periods. However,the concentrations in both feces and ruminal fluid increasedin all cattle when switched to the same high-corn diet in thefinishing period. There was no effect (P > 0.25) of dietor genotype during either period on E. coli O157 shedding infeces. Forty-one percent of the steers were positive for Campylobacterspp. at least once during the study, and repeated isolationsof Campylobacter spp. from the same steer were common. Theserepeated isolations from the same animals may be responsiblefor the apparent diet (P = 0.05) and genotype effects (P = 0.02)on Campylobacter in feces in the finishing period. Cells bearingstx genes were detected frequently in both feces (22.5%) andruminal fluid (19.6%). The number of stx-positive fecal sampleswas greater (P < 0.05) for $1/2$ Brahman steers (42.9%) than for $1/4$ Brahman (25.0%) or $3/4$ Brahman steers (22.2%), but were not differentcompared with MARC III steers (38.3%). The greater feed consumptionof $1/2$ Brahman and MARC III steers may have resulted in greaterstarch passage into the colon, accompanied by an increase infecal bacterial populations, which may have further improvedthe ability to detect stx genes in these cattle. There was nocorrelation between either ADG or daily DMI and the number ofpositive samples of E. coli O157, Campylobacter spp., or stxgenes, which agrees with our current understanding that thesemicroorganisms occur commonly in, and with no measurable detrimentto, healthy cattle.

Key Words: beef cattle • Bos indicus • Campylobacter • Escherichia coli O157 • forage • grain

INTRODUCTION

Top
Abstract
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
LITERATURE CITED

Maximizing animal performance through improved genetics andnutrition has been a primary effort of animal production research.Recently, there have been concerns about the environmental effectsof cattle production practices, which are focused primarilyon nutrient and bacterial contamination and emissions issuesassociated with manure accumulation and handling. Cattle nutritionhas been shown to be a valuable part of the solution to theproblems of excess nitrogen and phosphorus excretion (Klopfensteinand Erickson, 2002; Satter et al., 2002). Whereas it is likelythat modifying animal diets will play a role in minimizing theproblems associated with fecal bacteria excretion and odor,there is no agreement yet on the effects of cattle diets onthe prevalence and shedding of Escherichia coli O157 and otherzoonotic pathogens (Bach et al., 2002; Callaway et al., 2003;Vanselow et al., 2005). Human waterborne disease caused by E.coli O157 and Campylobacter jejuni has been linked to watersupply contamination with runoff containing bovine manure (O’Connor,2002). Furthermore, foodborne illness caused by E. coli O157,Salmonella spp., and Campylobacter spp. is commonly associatedwith consumption of undercooked beef and raw milk (CDC, 1993,2002, 2006). An objective of these experiments was to assessthe influence of bovine genotype and diet on the prevalenceof E. coli O157, Salmonella spp., and Campylobacter spp. ingrowing-finishing beef cattle, and the numbers of generic E.coli in ruminal contents and feces of these cattle. There isno information regarding differences in carriage of bacterialpathogens by Bos taurus vs. Bos indicus cattle. Among otherdifferences, Bos indicus cattle are more resistant to some parasitesthan Bos taurus cattle (Frisch, 1976; Frisch et al., 2000).The influences of genotype and diet on steer performance andmanure odor compound production are addressed in the companionarticles (Ferrell et al., 2006; Miller et al., 2006).

MATERIALS AND METHODS

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Abstract
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
LITERATURE CITED

Animals, Feeding, and Sample Collection
All animal procedures were reviewed and approved by the US MeatAnimal Research Center Animal Care and Use Committee.

Breeding, management, feeding, and the experimental diets ofthe 51 steers utilized for this study are described in detailin the accompanying article by Ferrell et al. (2006). The 4genotypes examined were of varying proportions of Brahman andMARC III (Bos taurus) genotypes, with 15, 20, 7, and 9 animalsof 0, $1/4$ , $1/2$ , and $3/4$ Brahman, respectively. The MARC III cattle area composite population composed of $1/4$ each of Hereford, Angus,Pinzgauer, and Red Poll. At 28 d after weaning, approximatelyequal numbers of each breed type were allotted among 8 pens,to become adjusted to using individual Calan-Broadbent electronicheadgates (American Calan, Inc., Northwood, NH) over a 28-dperiod.

During the entire 56-d postweaning period, all steers were feda 50:50 blend of the 2 experimental grower diets. One diet was100% chopped bromegrass hay and the other diet was primarilycorn silage (87%; Ferrell et al., 2006). At the end of the 56-dpostweaning period, the steers were divided approximately equallybetween the 2 diets, with 4 pens assigned to each diet. Steerswere individually fed 1 of these 2 diets ad libitum for a 119-dgrowing period, then all animals were gradually switched overa 2-wk interval to the same finishing diet, which was composedprimarily of 70% ground corn and 24% corn silage (Ferrell etal., 2006). Steers were fed this diet during the finishing perioduntil they reached a final target BW of 560 kg. Steers wereweighed at the beginning and end of the growing period, andat 14-d intervals throughout the growing and finishing periods.Feces and ruminal fluid were collected for microbial analysesthrough d 196 of the study (d 77 of the finishing period), whenthe first steers had reached the target BW. These samples werecollected before the daily feeding.

Fecal samples were collected directly from the rectum of eachsteer on d 0, 7, 28, 56, 84, 112, 126, 133, 154, and 196. Aclean latex glove covered with a new, clean, shoulder-lengthglove was donned for collection of each sample. Ruminal fluidsamples were collected by stomach tube and vacuum pump fromeach steer on d 14, 42, 70, 98, 140, and 182. A separate sanitizedstomach tube and sterile polypropylene filter flask were usedfor collection of each ruminal fluid sample. All samples weretransported to the laboratory for immediate processing.

Microbial Analyses
For isolation of E. coli O157, 5 g of feces or 5 mL of ruminalfluid was placed into a sterile filtered sample bag (SpiralBiotech, Norwood, MA), 45 mL of tryptic soy broth (TSB; Becton,Dickinson and Company, Sparks, MD) were added, and the bag contentswere blended with a Stomacher 400 Circulator (200 rpm, 1 min;Seward Limited, London, UK). After the removal of a 1- to 2-mLaliquot to a sterile test tube for bacterial population determinations(described below), the remaining sample was enriched by incubationat 37°C for 7 h. After this incubation, an additional 1mL of each enriched sample was measured into a labeled vialcontaining 1 mL of sterile TSB containing 0.5% yeast extractand 50% glycerol, which was frozen at –20°C for laterstx gene PCR, as described below.

One-milliliter volumes of the nonselective enrichments weresubjected to immunomagnetic separation and concentration asdescribed by Berry and Miller (2005) using Dynabeads anti-E.coli O157 (Dynal Biotech ASA, Oslo, Norway). Fifty microlitersof the concentrated bead suspensions was plated onto sorbitolMacConkey agar plates containing 0.05 µg of cefixime/mLand 2.5 µg of potassium tellurite/mL, and plates wereincubated at 37°C for 20 to 22 h before examination forcharacteristic sorbitol-negative E. coli O157 colonies. Suspectcolonies were tested for agglutination with E. coli O157 latextest reagents (Oxoid Ltd., Basingstoke, UK). Latex-agglutinatingisolates were further confirmed as E. coli by biochemical testing(Hitchins et al., 1998) and as E. coli O157 by PCR screeningfor the genes stx₁, stx₂, eaeA, EHEC hlyA, and rfbE_O157 (Patonand Paton, 1998).

For isolation of Campylobacter spp., 1 swabful of feces (approximately1 g) or 1 mL of ruminal fluid was placed into 13.5 mL of Boltonselective enrichment broth (Oxoid), mixed by inversion, andthen incubated at 37°C for 4 h, followed by incubation at42°C for 20 h. Twenty microliters of this enrichment wasstreaked onto Campy-Cefex agar plates (made according to Sternet al., 1992), which were incubated microaerobically at 42°Cfor 48 h in anaerobic jars containing CampyGen (Oxoid). Characteristiccolonies were confirmed serologically using PanBio-Campy (jcl)latex agglutination reagents (PanBio, Inc., Columbia, MD). Thesepresumptive Campylobacter spp. were further confirmed and speciatedby hippurate hydrolysis testing and by PCR screening for genesspecific for thermophilic Campylobacter spp., Campylobacterjejuni, or Campylobacter coli (Eyers et al., 1993; Fermérand Engvall, 1999; Cloak and Fratamico, 2002).

The experimental samples were examined for the presence of Salmonellaspp. utilizing method 2 described in Davies et al. (2000), using1 swabful of feces or 1 mL of ruminal fluid. Suspect colonieswere tested for agglutination with Salmonella latex test reagents(Oxoid) and were further tested for typical reactions on triplesugar iron and lysine iron agar slants after incubation at 37°Cfor 24 h.

The retained fecal and ruminal fluid enrichments were examinedby PCR for determination of the presence of the Shiga toxingenes stx₁ and stx₂. Cells were concentrated from 100 µLof the thawed samples by centrifugation (12,000 x g). Cell pelletswere resuspended in 400 µL of sterile, distilled, deionizedwater, concentrated again, and resuspended in 100 µL ofsterile, distilled, deionized water. The resulting suspensionswere heated at 100°C for 15 min, then frozen at –20°Cuntil used in PCR reactions. Two-microliter volumes of thesecell lysates were used as template in 25-µL PCR reactions,using the reaction conditions and primers described by Patonand Paton (1998). Samples positive for E. coli O157 were presumedto be positive for stx genes. Samples were considered positivefor stx genes if stx₁, stx₂, or both, were detected after gelelectrophoresis.

For enumeration of the fecal bacterial populations, the reservedvolumes of the initial 10-fold TSB dilutions of feces or ruminalfluid were serially diluted further in 2% buffered peptone water.For generic E. coli and coliforms, 1-mL volumes were platedonto Petrifilm E. coli/coliform count plates (3M MicrobiologyProducts, St. Paul, MN), which were incubated at 37°C for24 h before counting. For Enterobacteriaceae, 1-mL volumes wereplated onto Petrifilm Enterobacteriaceae count plates (3M),which were incubated at 37°C for 24 h before enumeration.

The pH was determined from fecal samples diluted 1:6 in distilled,deionized water or from undiluted ruminal fluid samples, usinga thin (6 mm), gel-filled pH electrode (Broadley James Corp,Irvine, CA).

Statistical Analyses
Populations of bacteria from duplicate plates were averagedand transformed to log₁₀ colony-forming units per gram of fecesor log₁₀ colony-forming units per milliliter of ruminal fluid.For analyses of pathogen prevalence, fecal and ruminal fluidsample data were pooled and analyzed as a binomial distribution.The unit of observation was the individual steer. The modelincluded the fixed effects of diet (bromegrass hay or corn silage),genotype (breed type), diet x genotype, day, genotype x day,and diet x day, with day as a repeated measure [with an AR(1)error structure], and the random effects of pen(diet) and steerx genotype x pen(diet). The MIXED procedure of SAS (SAS Inst.,Inc., Cary, NC) was used for analysis of the data. Differenceswere considered significant at P < 0.05 and a tendency wasdeclared when the P-value ranged from P = 0.05 to P < 0.10.Posthoc mean separation was done using a modified Student’st-test.

RESULTS AND DISCUSSION

Top
Abstract
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
LITERATURE CITED

Effects of grain vs. forage diets on the prevalence, shedding,and duration of shedding of E. coli O157 or generic E. coliby cattle have been the topic of several studies, but thereis no agreement on the role that diet may play in these occurrences(as recently reviewed by Bach et al., 2002; Callaway et al.,2003; Vanselow et al., 2005). Reasons for the contradictoryconclusions of these various works are likely due all or inpart to such differences as the diets examined (different grainsand forages), the length of feeding or feed switches (includingfasting), the age and type of cattle utilized (adult cattleand young calves; beef and dairy animals), the species utilized(cattle and sheep), and the use of naturally colonized cattlevs. experimentally inoculated cattle. One of our goals for thecurrent study was to conduct a longer term, diet-effect studyexamining the relevant target population of naturally contaminatedfinishing beef calves throughout the growing and finishing periods.In addition to determining the influence of genotype and dieton the carriage and shedding of E. coli O157, the influenceson Salmonella spp., Campylobacter spp., and other fecal bacteriawere also assessed, because limited information is availableregarding potential influence of cattle diet on the carriageand shedding on these zoonotic pathogens.

Generic E. coli populations in bovine feces did not differ (P> 0.22) by steer genotype in either the growing or finishingperiod (Figure 1). Furthermore, these populations did not differ(P = 0.11) by diet in the growing period, and tended to differ(P = 0.10) in the finishing period by diet fed in the growingperiod. However, these generic E. coli fecal populations weregreater (P < 0.001) in the finishing period than in the growingperiod. In steers fed bromegrass hay and corn silage, mean E.coli concentrations during the growing period ranged from 4.99to 5.56 and 5.21 to 5.94 log₁₀ cfu/g of feces, respectively.These E. coli populations increased after the switch from eitherbromegrass hay or corn silage to the high-concentrate finishingdiet, to levels of 6.73 and 6.67 log₁₀ cfu/g of feces, respectively,by d 154. During the growing period, fecal pH was typically0.5 to 0.6 units lower (P = 0.002) for steers fed the corn silage-baseddiet than for steers fed the bromegrass diet (Figure 1). Regardlessof previous diet, fecal pH was lower (P < 0.03) after theswitch to the high-concentrate finishing diet, ranging frompH 5.3 to 5.9, and no longer differed (P = 0.67) between the2 dietary treatments. These results are similar to those ofothers reporting greater fecal populations of generic E. coliand lower colonic feces pH in cattle fed greater grain diets(Diez-Gonzales et al., 1998; Jordan and McEwen, 1998; Scottet al., 2000), although others have not observed these effectson coliform or E. coli populations (Keen et al., 1999). FecalpH did not differ (P > 0.16) by genotype in either the growingor finishing periods.

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Figure 1. Concentrations of generic Escherichia coli in feces (A, B), and pH of feces (C, D) plotted by diet and by genotype (proportion Brahman). One diet was 100% chopped bromegrass hay and the other diet was 87% corn silage. Steers were switched to the same high-concentrate diet (70% corn and 24% corn silage) at 119 d (arrow). The SE noted are the SE of the least squares means.

Similar to results observed for feces, generic E. coli concentrationsin ruminal fluid did not differ (P > 0.35) by diet or bygenotype in either period (Figure 2

). In addition, E. coli populationsincreased (P < 0.001) when switched to the finishing dietby greater than 1.0 log to a mean level of 4.23 log₁₀ cfu/mLof ruminal fluid, from a mean level of 2.93 log₁₀ cfu/mL inthe growing period. Unlike fecal pH, the pH of the ruminal fluiddid not differ (P = 0.72) between steers fed bromegrass hayor corn silage in the growing period. Similar to fecal pH, however,ruminal fluid pH decreased (P < 0.001) after the switch tothe finishing diet, from an average pH of 7.31 in the growingperiod to an average pH of 6.33 in the finishing period (Figure2

). Previous studies have reported that high-concentrate diets,as compared with high forage diets, can result in greater ruminalpopulations of E. coli and lower ruminal pH in cattle (Diez-Gonzaleset al., 1998

; Tkalcic et al., 2000

). Ruminal fluid pH differed(P = 0.01) by genotype in the finishing period. On d 140 and182, ruminal fluid pH of $1/2$ Brahman steers was greater (6.62 and6.46, respectively) than that of the MARC III steers (6.19 and6.11, respectively), but did not differ from the intermediateruminal fluid pH values of $1/4$ and $3/4$ Brahman steers ( $1/4$ : 6.45 and6.22; $3/4$ : 6.37 and 6.19, respectively). To our knowledge, breeddifferences in ruminal pH have not been observed, and may bea reflection of increased turnover rate as a result of relativelyhigh feed intake and reduced rumen size of the $1/2$ Brahman steers(Ferrell and Jenkins, 1998

; Ferrell et al., 2006

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Figure 2. Concentrations of generic Escherichia coli in ruminal fluid (A, B), and pH of ruminal fluid (C, D) plotted by diet and by genotype (proportion Brahman). One diet was 100% chopped bromegrass hay and the other diet was 87% corn silage. Steers were switched to the same high-concentrate diet (70% corn and 24% corn silage) at 119 d (arrow). The SE noted are the SE of the least squares means.

In both feces and ruminal fluid, coliform and Enterobacteriaceaepopulations were comprised primarily of generic E. coli. Asa result, coliform and Enterobacteriaceae population responsesparalleled those of E. coli populations (data not shown).

Escherichia coli O157 was not frequently isolated. From a totalof 816 fecal or ruminal fluid samples, E. coli O157 was recoveredfrom 24 samples (2.9%), including 21 fecal samples and 3 ruminalfluid samples. However, over the course of the entire study,19 of the 51 steers (37%) were E. coli O157-positive at leastonce; E. coli O157 was isolated only once from 15 steers, twicefrom 3 steers, and 3 times from 1 steer. This is in agreementwith previous reports that indicate that cattle tend to shedthis pathogen intermittently or transiently, although prolongedshedding has been described (Robinson et al., 2004). There wasno effect of diet fed during the growing period or genotype(P $≥$ 0.25) on the proportions of E. coli O157-positive fecalsamples in either the growing or finishing periods (Table 1;because only 3 of the 306 ruminal fluid samples were E. coliO157-positive, these samples were not included in the analysis).The proportions of E. coli O157-positive fecal samples tended(P = 0.09) to be greater in the finishing period. Rather thana response to the switch to the finishing diet, however, thistendency is likely a reflection of the seasonal variation ofshedding of this pathogen by cattle. Numerous studies have reportedseasonal differences in prevalence of fecal shedding of thispathogen; typically, the lower prevalences are reported in thecooler winter months and the greater prevalences are reportedin the warmer summer and early fall months (Van Donkersgoedet al., 1999; APHIS, 2001; Barkocy-Gallagher et al., 2003).The growing period of our study was initiated in early December,with the finishing period beginning in late March and endingin mid June. The isolation rates of E. coli O157 of 2.9% offecal samples collected in the growing period and 5.9% of fecalsamples collected in the finishing period are consistent withprevalence previously reported for these times of the year (VanDonkersgoed et al., 1999; APHIS, 2001; Barkocy-Gallagher etal., 2003), and our overall low isolation of this pathogen islikely due to conducting the study during this time of year.

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Table 1. Prevalence of Escherichia coli O157, Campylobacter spp., and stx genes in feces and ruminal fluid of steers during the growing and finishing periods¹

Salmonella was isolated only once during the study, on d 14in a ruminal fluid sample taken from a $1/4$ Brahman steer fed bromegrasshay. Previous studies have reported low frequencies of infectionof Salmonella shedding by feedlot cattle in North America (Fedorka-Crayet al., 1998

; Van Donkersgoed et al., 1999

; Sorensen et al.,2002

Campylobacter spp. were isolated from 47 fecal samples and 1ruminal fluid sample over the course of the entire study (5.9%of 816 samples). Forty-four isolates were identified as C. jejuni,and 3 isolates were identified as Campylobacter coli. The 3C. coli-positive fecal samples were obtained from 2 steers inthe same pen; both steers were positive on d 0, and 1 steerwas positive again on d 7. This is consistent with previousinformation reporting that of these 2 species, C. jejuni ismore commonly found in cattle than is C. coli (Nielsen et al.,1997; Wesley et al., 2000; Bae et al., 2005).

Twenty-one of 51 steers (41%) yielded a Campylobacter-positivesample at least once during the study, and many of these animalswere positive multiple times. Campylobacter was isolated oncefrom 10 steers, twice from 4 steers, 3 times from 3 steers,4 times from 1 steer, 5 times from 2 steers, and 7 times from1 steer. These results corroborate those of Inglis et al. (2004),who found that a high percentage of Angus-cross steers repeatedlyshed Campylobacter spp. over a 4-mo period. There was an effectof genotype (P = 0.02) on Campylobacter fecal shedding in thefinishing period (Table 1). However, this observation shouldbe interpreted with caution. Given the low prevalence of Campylobacter-positivesamples, this genotype effect is likely due to the presenceof "chronic shedders" within genotype groups, namely one $1/2$ Brahmansteer with 4 positive samples and 2 MARC III (0 Brahman) steerswith 2 positive samples each during the finishing period. Furtherwork would be needed to determine if chronic or protracted Campylobactershedding is linked to breed type.

Similarly, additional research may be warranted to determineif cattle diet affects the duration of Campylobacter shedding.In both the growing and finishing periods, the proportion ofCampylobacter-positive samples tended (P = 0.06 and P = 0.05,respectively) to be greater for steers fed bromegrass hay duringthe growing period (Table 1). Steers in pens 4, 6, and 8 werefed the brome-grass hay diet, and these 3 pens had the greatestnumbers of Campylobacter-positive samples at 9, 13, and 9 positivesamples, respectively, over the entire study. Each of thesepens contained 1 or more steers that chronically shed this pathogen:pen 4 housed 1 steer with 4 positive samples and 1 steer with5 positive samples; pen 6 housed 2 steers with 3 positive samplesand 1 steer with 5 positive samples; and pen 8 housed 1 steerwith 7 positive samples. (Pen 2 steers, also fed bromegrasshay, had 3 Campylobacter-positive samples, including 1 steerwith 2 positive samples.) Whereas samples from these animalsmade up the majority of the Campylobacter-positive samples fromthese pens, the persistence of the pathogen within the pen dueto chronic shedding would facilitate horizontal transmissionto other steers within the pens. Thus, as with the genotypeeffect on Campylobacter-positive fecal samples in the finishingperiod, the observed diet effect may be due in part to steersproviding multiple positive samples. However, it is also possiblethat the effect is a true diet effect, and that cattle fed bromegrasshay may shed Campylobacter spp. for protracted periods. Increasedduration of shedding of E. coli O157:H7 by cattle fed foragediets compared with high-grain diets of corn or barley has beenreported (Hovde et al., 1999; Van Baale et al., 2004). However,it is important to note that repeat shedders of Campylobacterspp. also were present among steers fed the corn silage-baseddiet, including 4 animals with 2 positive samples each and 1animal with 3 positive samples. In addition, many of the steerscontinued to shed after the switch to the greater concentratefinishing diet, suggesting a lack of "true" diet effect. Furthermore,the chronically shedding steers described by Inglis et al. (2004)were fed a high-concentrate diet based on steam rolled barley.

The prevalence of Campylobacter-positive fecal samples was notdifferent (P = 0.64) in the growing and finishing periods. Althoughstudied less thoroughly than E. coli O157:H7, seasonal changesin Campylobacter shedding by cattle, with peaks in prevalenceoccurring both in the spring and fall, have been described (Stanleyet al., 1998). Overall, our sample isolation rate of Campylobacterspp. was somewhat lower than might be expected, given the reportsof other studies in beef cattle. Using PCR detection, Ingliset al. (2004) found during their 4-mo study that 100 and 31.7%of beef steers shed Campylobacter spp. and C. jejuni at leastonce, respectively, and that 86% of the steers shed Campylobacterspp. 4 times or more. Using cultural isolation procedures, Baeet al. (2005) found 31.6 and 13.3% of feedlot cattle fecal samplespositive for C. jejuni and C. coli, respectively. Stanley etal. (1998) isolated thermophilic Campylobacter spp. from thesmall intestine contents of 89.4% of beef cattle at slaughter.These differences in prevalence may be due to a number of reasons,in addition to the use of different detection methodologies(cultural vs. PCR-based), but it is clear that thermophilicCampylobacter spp. are widely distributed in cattle.

Feces and ruminal fluid sample enrichments were examined byPCR for the presence of stx₁ and stx₂ genes, as a means of estimatingthe incidence of Shiga toxin-producing E. coli (STEC), includingnon-O157:H7 STEC, and other Shiga toxin gene-bearing cells,in response to differences in steer genotype and the diet regimens.Whereas E. coli O157 is the STEC serotype most commonly associatedwith food- and waterborne disease, numerous other STEC serotypes,including O26, O55, O111, O145, O103, and O121, have also beenlinked to human illness (Nataro and Kaper, 1998; Bettelheim,2003). Although it is clear that not all STEC are pathogenic,it is becoming apparent that STEC, and possibly other stx-bearingbacteria, are commonly present in the bovine gastrointestinaltract.

In contrast to either E. coli O157 or Campylobacter spp., stxgenes were detected more frequently overall, and were also commonlydetected in ruminal fluid (Table 1). Over the entire study,one or both stx genes were detected in 115 of 510 fecal samples(22.5%) and 60 of 306 (19.6%) ruminal fluid samples. Fifty ofthe 51 steers had a stx-positive fecal or ruminal fluid sampleat least once. These results agree with those of other recentstudies that have reported the frequent occurrence of STEC andstx genes in beef cattle. In an examination of beef cattle atslaughter, Barkocy-Gallagher et al. (2003) found that 34.3%of fecal samples were positive for stx genes by PCR. Of thesefecal samples, 19.3 and 5.9% were positive for non-O157 STECand E. coli O157, respectively. Cobbold et al. (2004) reportedstx gene and STEC prevalences of 16 and 7.3%, respectively,in bovine feces from dairy, feedlot, and cow-calf operations.Shiga toxin-producing E. coli were recovered from 16.7% of fecalsamples from Australian dairy cattle, including the serotypesof O157:H7 (1.9% of samples) and O26:H11 (1.7% of samples; Cobboldand Desmarchelier, 2000). As noted above, stx genes were detectedin 60 of the 306 ruminal fluid samples, whereas E. coli O157was detected in only 3 of these samples. Although E. coli O157:H7has been isolated from ruminal contents of both naturally colonizedand orally inoculated animals (Van Donkersgoed et al., 1999;Buchko et al., 2000), it is generally understood that when present,like generic E. coli, E. coli O157:H7 normally inhabits andproliferates in the bovine lower gastrointestinal tract (Buchkoet al., 2000; Grauke et al., 2002; Van Baale et al., 2004).The presence of E. coli O157 in the rumen may reflect recentingestion from food, water, or the environment. However, aswe found, generic E. coli are typically present in the rumen,at reported concentrations ranging from 10¹ to 10⁵ cfu/mL orper g of ruminal fluid (Diez-Gonzales et al., 1998; Jacobsonet al., 2002). Thus, the high prevalence of stx genes in therumen, as well as the feces, may simply be a reflection of thewide distribution of STEC or other stx-bearing bacteria in cattleand the production environment. Van Donkersgoed et al. (1999)detected Shiga toxins (verotoxins) more commonly than E. coliO157:H7 in ruminal fluid samples from cattle at slaughter, at6.4 vs. 0.8%.

We note that multiple stx-positive samples (either feces orruminal fluid) were typical of most of the steers. The majorityof steers (58.8%) yielded stx-positive samples 3 or more times,including 1 steer with 9 positive samples and 3 steers with8 positive samples each. Additional work would be needed todetermine if this was due to chronic shedding, or if this isa reflection of the high prevalence of STEC or stx gene-bearingcells among cattle. As reviewed by Bettelheim (2003), thereare no effective media or efficient methods for the differentialisolation of general STEC, like those specifically availablefor E. coli O157:H7. Isolation of STEC generally has been accomplishedby PCR screening of samples for stx genes, followed by colonyblotting and hybridization procedures. However, recovery ofSTEC, including non-O157 STEC, from stx PCR-positive samplesusing these procedures can be quite low, with reported recoveriesranging from 38 to 84% (Arthur et al., 2002; Barkocy-Gallagheret al., 2003; Cobbold et al., 2004). For these reasons, we didnot attempt the recovery and characterization of non-O157 Shigatoxin-producing cells from stx-positive samples. The recentintroduction and continued development of additional specificimmunological reagents and other useful products should contributeto our understanding of the epidemiology and ecology of STECin cattle (Pearce et al., 2004).

There was no effect of diet or genotype (P > 0.29) on thepresence of stx genes in feces or ruminal fluid in the growingperiod (Table 1). In the finishing period, there was no effect(P > 0.31) of growing period diet on stx genes in eitherfeces or ruminal fluid. However, there was an effect of genotype(P = 0.01) on stx-positive fecal samples in the finishing period.The prevalence of stx-positive fecal samples was greater (P< 0.008) for $1/2$ Brahman steers (42.9%) than for $1/4$ Brahman steers(25.0%) or $3/4$ Brahman steers (22.2%), but were not different (P= 0.22) from MARC III (0 Brahman) steers (38.3%). As seen forCampylobacter, there was a contribution to this effect fromsteers providing multiple stx-positive samples. Although thesemultiple samples might be due to chronic infection (which maybe animal-specific or bacteria strain-specific), the repeatedshedding might also be due to repeated colonization by differentstx-bearing cells. Thus, it is uncertain if breed type influenceseither (1) the colonization of cattle by stx-bearing cells,or (2) the duration of colonization/shedding by these stx-bearingcells, or both. Additional work would be needed to confirm andclarify this effect. Regarding genotype effects on STEC shedding,Riley et al. (2003) noted a possible breed effect on the proportionof E. coli O157:H7-positive fecal samples in beef cows, althoughthey qualified that this result may have been confounded byother variables.

Another plausible explanation for this genotype effect on stx-positivefecal samples may be related to genotype effects on steer performance.In the companion paper to this work, Ferrell et al. (2006) foundthat feed consumption (daily DM, CP, and ME intake) and ADGof $1/2$ Brahman and MARC III steers were similar, and were greaterthan that of $1/4$ and $3/4$ Brahman steers, which is consistent withexpected greater levels of heterosis for these traits in theseanimals. In the same fashion that consumption of high-concentratediets by cattle can result in increased starch in the colonand a concomitant increase in fecal E. coli populations (Diez-Gonzaleset al., 1998; Jordan and McEwen, 1998; Scott et al., 2000),the increased feed intake by $1/2$ Brahman and MARC III steers mayhave further increased starch content in colon contents, thusincreasing the numbers of stx-bearing cells, and thereby improvingour ability to detect stx genes. This idea is supported by recentresults of Gilbert et al. (2005), who found that fecal concentrationsof enterohemorrhagic E. coli virulence genes, including stx₁,were greater in cattle fed a high grain diet compared with thosefed diets of roughage or roughage plus 50% molasses. The effectof increased feed intake and any concomitant increased colonicstarch is not reflected in the E. coli counts that we foundin feces, which did not differ (growing period, P = 0.97; finishingperiod, P = 0.22) by genotype. However, stx genes do occur inspecies other than E. coli (Lindberg et al., 1998). The relativesensitivity of the PCR protocol has not been established andwe used a crude DNA preparation method to provide template forthe PCR. However, given the sensitivity of PCR, only subtleincreases in the populations of the target cells containingthe stx genes might be needed to improve the ability to detectthese genes. Indeed, the greater prevalence of E. coli O157in cattle fed high-grain diets that has been reported by somestudies may be directly related to increases in their populationsin the feces in response to the diet, which would improve theability to detect them, should they be present.

The prevalence of stx-positive samples increased (P = 0.001)in the finishing period, primarily due to an increase (P = 0.001)in the prevalence of positive fecal samples. This may be aneffect of the switch from the growing diets of bromegrass hayand corn silage to the high-concentrate finishing diet, butmay also be due to seasonal variation. Seasonal differencesin the prevalence of general STEC or stx genes in cattle havebeen reported, although this aspect has not been as well studiedas it has for E. coli O157:H7. Cobbold et al. (2004) found thatboth STEC and stx gene prevalence were greater for fall thanfor winter, similar to E. coli O157:H7 prevalence. In beef cattlefeces at slaughter, non-O157 STEC and stx genes were more prevalentin spring and fall than in summer and winter (Barkocy-Gallagheret al., 2003).

To ascertain if there was any association between pathogen carriageand measures of feed efficiency, we examined the relationshipsbetween the numbers of pathogen- or stx gene-positive samplesobtained from each steer, and its ADG and daily DMI (Ferrellet al., 2006). There was poor correlation between the numberof positive samples of either pathogen or of stx genes obtainedfrom each steer, and the ADG or daily DMI of these steers (datanot shown). This agrees with many previous observations thatindicate that cattle generally are asymptomatic carriers ofthese pathogens (Stanley et al., 1998; Dean-Nystrom et al.,1999; Wesley et al., 2000).

In summary, for the diets examined, clear-cut effects of dietor genotype on the prevalence of carriage and shedding of E.coli O157 or Campylobacter spp. by cattle were not observed.Rather, this study highlighted additional potential confoundingvariables that can influence the interpretation of the resultsof long-term feeding studies, including seasonal variationsof pathogen shedding, chronic shedding of pathogens, and horizontaltransmission of pathogens among animals. In comparison to suchzoonotic pathogens as E. coli O157 or Salmonella, relativelylittle is known about Campylobacter colonization of beef cattle.This work confirms recent reports of chronic shedding of thismicroorganism by cattle, and additional examination is plannedto determine roles for chronic shedding and horizontal transmissionin the maintenance of Campylobacter spp. in cattle. Our resultsalso corroborate the common occurrence of stx gene-bearing cellsin cattle. The greater feed consumption by the $1/2$ Brahman andMARC III cattle may be responsible for the greater proportionsof stx gene-positive fecal samples in these steers during thefinishing period. As was the case for generic E. coli populationsin feces and ruminal fluid when cattle were switched to thehigh-concentrate diet, we speculate that stx gene-bearing celllevels increased in response to the greater starch load in thecolon, thus improving the detection of these genes.

Footnotes

¹ Mention of a trade name, proprietary product, or specific equipmentdoes not constitute a guarantee or warranty by the USDA anddoes not imply approval to the exclusion of other products thatmay be suitable.

² The authors acknowledge the technical assistance of J. Long,C. Felber, and T. Post, and the secretarial assistance of J.Byrkit.

⁴ Present address: USDA-ARS, Soil & Water Conservation ResearchUnit, 121 Keim Hall, East Campus, University of Nebraska, Lincoln,NE 68583-0937.

³ Corresponding author: berry{at}email.marc.usda.gov

Received for publication December 21, 2005. Accepted for publication April 21, 2006.

LITERATURE CITED

Top
Abstract
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
LITERATURE CITED

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