Utilising Vaccination for Porcine Circovirus Type 2 as a Tool to Aid Elimination of PCV2 from Swine Populations

Porcine circovirus virus 2 (PCVs) vaccine can affect viral circulation on farms but would need to be used in conjunction with other management practices to eliminate PCV2 from most pig populations, reported M.L. Potter of Abilene Animal Hospital and co-authors to Kansas Swine Day 2011.
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Summary

A total of 928 pigs from the Swine Teaching and Research Centers at Michigan State University (MSU) and Kansas State University (KSU) and a Kansas commercial farm were used during a three–year study to determine whether circovirus vaccination influenced porcine circovirus type 2 (PCV2) circulation within a herd and could be used as a tool to eliminate PCV2 from PCV2–positive swine herds. Infection with PCV2 was confirmed in both university herds before circovirus vaccine introduction.

After vaccination implementation, vaccinated barrows from consecutive groups were serially tested for viraemia. Follow-up antibody and growth testing with vaccinated and non–vaccinated pigs was performed at the KSU farm. In a circovirus-vaccinated commercial herd, testing of non-circovirus-vaccinated pigs for viraemia was completed. Environmental swab samples were collected from facilities at the KSU and commercial farms for PCV2 DNA detection.

Sera from none of the nine MSU vaccinated-cohorts and three of 10 KSU vaccinated-cohorts had detectable PCV2 DNA. From follow-up testing, a PCV2 antibody rise after vaccination was detected for vaccinated pigs with no detectable antibody rise for non-vaccinated pigs. Overall growth rate of non-vaccinated pigs tended (P=0.07) to increase compared with vaccinated pigs. Non-vaccinated pigs became PCV2 viraemic at the commercial farm. Viral DNA was detected in the environment of the commercial farm but not in the KSU facilities.

Therefore, circovirus vaccine can affect viral circulation on farms but would need to be used in conjunction with other management practices to eliminate PCV2 from most swine populations.

Introduction

Infection with porcine circovirus type 2 (PCV2) can result in a multi-syndrome disease, porcine circovirus disease (PCVD).7 Identified in diagnostic laboratory samples in the early 1990s, PCV2 has affected most US swine herds. Despite a long history of PCV2 circulation within the swine population, vaccines against PCV2 have been commercially available only since 2006.8

Initial studies evaluating the effects of circovirus vaccination on production parameters in PCV2-affected herds indicate that vaccination was effective at reducing finishing phase mortality and increasing pig growth rate.9,10,11 In single-cohort studies, vaccination with commercial or experimental vaccines against PCV2 reduced viraemia10,11 and decreased viral shedding in nasal secretions and faeces12,13 but data evaluating the effects of vaccination on PCV2 viral circulation within a herd over time are limited.

The authors’ goal was to monitor PCV2 viral circulation in swine herds after implementing a circovirus vaccination programme for growing pigs. The short-term objective of this project was to determine whether circovirus vaccination could be used to affect viral circulation within two farrow-to-finish herds. The long-term objective of the project was to understand whether use of circovirus vaccines over time in PCV2–positive swine herds could provide a tool to eliminate PCV2 from these herds.

Procedures

Procedures used in these studies were approved by the Kansas State University and Michigan State University Institutional Animal Care and Use Committees.

Herd history

The MSU and KSU Swine Teaching and Research Centers were single-location farrow-to-finish operations. Pigs were moved through the KSU farm in an all–in, all–out manner in nursery, grower or finisher rooms. In the MSU farm, about half of the pigs placed in a nursery, grower, or finisher room were moved in and out at a time. Pigs were born (farrowed) at each farm approximately every four (MSU) or five (KSU) weeks, which resulted in growing pig populations of about 300 pigs in each age group.

Both herds were negative for porcine reproductive and respiratory syndrome virus (PRRSV) and the MSU herd was negative for Mycoplasma hyopneumoniae (M. hyo). Pigs at the KSU farm were vaccinated at weaning for M. hyo (RespiSure–ONE; Pfizer Animal Health, New York, NY), which, along with other management procedures, contributed to low levels of clinical disease. Prior to the start of our study, both farms had been closed to live animal introductions, but semen was introduced from outside sources. In October 2007, the KSU farm began to bring replacement gilts from an outside source into the herd approximately every nine weeks.

Clinical history

The KSU farm did not have any clinical signs of PCVD noted before the baseline testing and subsequent implementation of a circovirus vaccination programme, although prior to baseline testing, histopathologic evaluation on tissues of one pig documented lymphoid depletion lesions consistent with PCVD. The MSU farm had evidence of moderate clinical PCVD (10 to 15 per cent nursery mortality) prior to baseline testing.

Phase 1: Baseline testing procedures

In early 2007, a cross-sectional survey was conducted of both university herds to verify the presence of PCV2 and to characterise patterns of PCV2 infection and seroconversion. At the MSU farm, blood was collected from 101 pigs across a total of five growing pig populations (6 to 10, 11 to 15, 16 to 20, 21 to 25, and 26 to 30 weeks of age). Within the KSU farm, 141 pigs were sampled across five growing pig populations (four, nine, 14, 19 and 24 week of age). Serum was pooled (MSU: 21 pools; KSU: 27 pools) within age group and analyzed using the Kansas State Veterinary Diagnostic Laboratory (KSVDL) PCV2 PCR assay for detection of PCV2 nucleic acid. Viral template quantities for each serum pool were log10 transformed and transformed results were averaged for pools within each age range to characterise the changes in viral load.

For the detection of PCV2 antibodies, individual serum samples were tested using the 96-well format KSVDL PCV2 indirect fluorescent antibody (IFA) assay with serial 1:2 dilutions beginning with a 1:20 serum to phosphate-buffered saline dilution and ending with a 1:2,560 ratio. The titration end–point was calculated as the reciprocal of the last serum dilution that gave a positive result.

All IFA titres were log2 transformed to approximate a normal distribution prior to descriptive analysis. For samples that did not have antibody detected at the most concentrated dilution (1:20), the log2 of 10 was used in the analysis. For samples that were strongly positive at the least concentrated dilution (1:2,560), the log2 of 5,120 was used. This approach allowed results to be weighted differently than samples with antibody detected with a normal level of fluorescence at the 1:20 and 1:2,560 dilutions.

Infection and antibody profiles obtained from the baseline testing were considered when deciding on sampling times for the Phase 2 study on each farm.

Phase 2: Trial procedures

In the spring of 2007, both MSU and KSU initiated circovirus vaccination programmes. A two-dose circovirus vaccine (Circumvent PCV; Intervet/ Schering-Plough, Millsboro, DE) was administered as an intramuscular injection (2mL per dose) to all growing pigs in each weaning group with three to five weeks between vaccine doses. Pigs were weaned and vaccinated with the first dose of circovirus vaccine at approximately three weeks of age at the KSU farm, but weaning age and timing of first vaccination at the MSU farm varied (range: two to six weeks).

From 2007 through 2008, barrows from consecutive weaning cohorts at the MSU (nine groups) and KSU (10 groups) farms were monitored for PCV2 viraemia. A minimum of 12 barrows per group from different litters were randomly selected, ear-tagged and serially bled at four time–points: weaning or just before vaccination, entry-to-finishing, mid-finishing and end-of-finishing. After completion of data collection in 2008, individual serum samples for pigs with complete serum sets (four serum samples per pig) were tested by the KSVDL PCV2 PCR assay for detection of PCV2 nucleic acid. An average of 40 cycles was run with a cycle time threshold of 0.05 for classification of PCV2 nucleic acid-containing (positive) samples.

Phase 3: Follow-up monitoring procedures

Beginning in the spring of 2009, a total of 372 pigs (186 non-vaccinated control pigs and 186 circovirus–vaccinated pigs) across three weaning groups were used in a Phase 3 growth and PCV2 antibody follow-up study at the KSU farm. At the start of the Phase 3 study, the KSU farm had been vaccinating pigs against PCV2 for the previous two years. During that time, there had been no evidence of clinical disease. A first objective of this follow–up study was to document the effects of circovirus vaccination on PCV2 antibody titres and to determine whether there was evidence of PCV2 exposure. A second objective of this Phase 3 study was to evaluate the effects of circovirus vaccination on growth rate of pigs in the KSU herd.

Three groups of pigs were used in the Phase 3 study. Groups 1 and 2 had seven pigs per nursery pen. A total of 18 barrow pairs (36 pigs; one pair in each of 18 pens) for group 1 and 30 barrow pairs (60 pigs; one pair in each of 30 pens) for group 2 were utilised. Within a pen, a pair of barrows was selected with one barrow per pair randomly allotted to a vaccinated treatment and the pen–mate barrow assigned to the non-vaccinated control treatment. Barrows assigned to the vaccinated treatment were injected intramuscularly with a two–dose circovirus vaccine (Circumvent PCV) at approximately three and six weeks of age. All other pigs in the weaning group not enrolled in the follow-up study were vaccinated with the same two–dose circovirus vaccine.

Throughout the entire study, pairs of barrows remained penned together. Barrows were individually weighed and bled at four time points: day 0 (pre-vaccination), entry–to–finisher, mid–finishing, and end–of–finishing. From these data, average daily gain (ADG) was calculated for three periods: nursery and grower, finisher and overall nursery to finisher. Removals and mortalities were recorded and weighed and their gain and time on test were included in performance calculations.

For group 3, 138 barrow or gilt pairs (276 pigs) were randomly allotted to treatments (vaccinated or non-vaccinated control) at the time of weaning with procedures similar to those used for groups 1 and 2. For group three, six or eight pigs were assigned to each nursery pen (three or four pairs within a pen) and all pigs were placed on test. Pigs assigned to the vaccinated treatment were injected intramuscularly with a two–dose circovirus vaccine (Circumvent PCV) at approximately three and nine weeks of age. Weighing and penning procedures for each pair were similar to those used for groups 1 and 2. A subset of 20 barrow pairs (40 pigs) from 20 different pens distributed throughout the nursery were bled at the time of weighing. Pairs of barrows were selected and, within each pair, one barrow was randomly assigned to a vaccinated treatment and the pen–mate barrow assigned to the non-vaccinated control treatment. For group 3, removals and mortalities were recorded and weighed and their gain and time on test were included in performance calculations.

Individual serum samples for groups 1, 2 and 3 were tested for PCV2 antibodies using the KSVDL IFA assay. Test procedures used were similar to those used in Phase 1. However, an initial serum to phosphate-buffered saline dilution of 1:40 was used with subsequent serial 1:3 dilutions for group 1, 2 and 3 samples. Testing was performed over seven days (two days for group 1, three days for group 2, and two days for group 3), and pairs of pigs were balanced across IFA days within each study.

Group 1, 2, and 3 IFA titres were log3 transformed to approximate a normal distribution prior to statistical analysis. For samples that did not have antibody detected at the most concentrated dilution (1:40), the log3 of 13.3 was used in the analysis, whereas the log3 of 262,440 was used for analysis for samples that were strongly positive at the least concentrated dilution (1:87,480). This approach allowed these samples to be weighted differently than positive samples with normal level fluorescence at 1:40 and 1:87,480.

Group 1, 2 and 3 IFA data were analysed by repeated measures analysis using the GLIMMIX procedure in SAS version 9.1.3 (SAS Institute, Inc., Cary, NC). Fixed effects in the model included treatment, time and their interaction. Group and IFA day were used as random effects. Differences between treatments were determined using least squares means (P<0.05). Log3 transformed least squares means were transformed back to the original scale for presentation as geometric mean titres (GMT).

Growth data were analysed using the GLIMMIX procedure in SAS version 9.1.3. The interaction with gender and treatment was determined to be non-significant for group 3, and growth data were pooled across the genders for subsequent analysis of the treatment effect. Thus, growth data for all three groups were analysed using a single model. Treatment was a fixed effect and group was included as a random effect. Differences between treatments were determined using least squares means (P<0.05).

Phase 4: Monitoring for PCV2 under commercial conditions

A commercial farm in Kansas that was determined to have had severe PCVD before circovirus vaccine became available was selected as a herd for an additional monitoring study (Phase 4) because of proximity and clinical history. Prior to the introduction of circovirus vaccine, post–weaning mortality had ranged from five to nine per cent. After implementation of a circovirus vaccination program (Circumvent PCV), the herd had less apparent clinical disease (mortality: four to nine per cent). The circovirus vaccination programme had been in place for a year before the Phase 4 study began. In addition to the history of PCV2 infection, PRRSV and M. hyo also contributed to the health challenges in the nursery and finishing phases of production. Pigs were weaned from a sow farm in western Kansas and moved to eastern Kansas to be placed at a nursery–finishing site with two nursery barns with four rooms each and eight finishing barns. Pigs were moved all–in, all–out by nursery room and finishing barn.

A total of 85 pigs (1.7 to 3.1 weeks of age) from a 1,100–pig weaning group were ear-tagged and bled just prior to weaning. These 85 pigs were not vaccinated against PCV2 and were monitored for 9 weeks. All other pigs in the weaning group were vaccinated according to standard farm protocol with a 2-dose circovirus vaccine (Circumvent PCV). The 85 non-vaccinated sentinel pigs were initially penned in four pens in the nursery room that also contained pens of circovirus–vaccinated pigs. If pigs were removed from their initial pens because of illness or injury, they were moved to a sick pig pen but were still monitored. After approximately eight weeks in the nursery, pigs were moved to a single finisher barn at the same farm location and were placed in pens according to their vaccination status. Pigs were bled approximately every three weeks for a total of four sampling times (sampling time age ranges: 1.7 to 3.1, 4.9 to 6.3, 7.9 to 9.3, and 10.9 to 12.3 weeks of age). The objective of this monitoring effort was to determine whether non-vaccinated pigs housed in barns with pigs vaccinated against PCV2 became viraemic with PCV2 after circovirus vaccine was used in the herd for a year.

Serum samples were pooled (five samples per pool) within age range and were analyzed by the KSVDL PCV2 PCR assay for presence of PCV2 nucleic acid. Genotype of PCV2 (PCV2a or PCV2b) was determined for samples with detectable PCV2 nucleic acid.

Phase 5: Monitoring for PCV2 in the environment of swine barns

As pigs involved in all previous phases of this study were exposed to different environments and pigs over time, we wanted to determine whether documentable sources of PCV2 exposure existed. The objective for this phase of monitoring was to demonstrate applicability of swabbing and PCV2 PCR testing as a method for monitoring PCV2 levels on environmental surfaces in swine production facilities.

Swab samples were collected from the nursery and finisher rooms at both the KSU farm and the commercial farm in eastern Kansas that was used in the Phase 4 study. Cotton swabs were used to sample the floor slats, gating, waterers, feeders, fans and heaters in the nursery or finishing rooms. Swabs were placed in vials containing enriched media. For each farm, samples were pooled within nursery or finishing production phases (two KSU nursery or finishing pools and 16 commercial farm nursery or finishing pools). A uniform amount of this pooled suspension was tested by KSVDL PCV2 PCR for detection of PCV2 nucleic acid.

Results

Phase 1

Baseline PCV2 IFA testing of the serum collected from pigs from the MSU herd demonstrated that passively acquired antibody declined by 15 weeks of age (Figure 1). Higher levels of antibody were apparent in pigs 16 to 20 weeks of age or older. PCV2 nucleic acid was detected by PCR in serum samples from pigs 11 to 15 weeks of age and older (Figure 2).


Figure 1. Characterisation of the porcine circovirus type 2 (PCV2) antibody profile of the Michigan State University (MSU) Swine Teaching and Research Center herd prior to implementation of a circovirus vaccination programme.
At the MSU farm, a total of 101 pigs were sampled across five growing pig populations (six to 10, 11 to 15, 16 to 20, 21 to 25, and 26 to 30 weeks of age) using a cross-sectional design. Serum samples from individual pigs were tested by the Kansas State University Veterinary Diagnostic Laboratory PCV2 indirect fluorescent antibody (IFA) assay for detection of PCV2 antibodies. All IFA titres were log2 transformed to approximate a normal distribution prior to descriptive analysis. Resulting transformed means were transformed back to the original scale for presentation as geometric mean titres (GMT).


Figure 2. Characterisation of the porcine circovirus type 2 (PCV2) infection profile of the Michigan State University (MSU) Swine Teaching and Research Center herd prior to implementation of a circovirus vaccination programme.
Serum was pooled (MSU: 21 pools) within age group and analysed using the Kansas State University Veterinary Diagnostic Laboratory PCV2 PCR assay for detection of PCV2 nucleic acid. Pooled results were log10 transformed and transformed results were averaged within age ranges to characterise patterns for viral load.

In the baseline analysis of the KSU herd (Phase 1), passively acquired antibody in growing pigs declined by 19 weeks of age with higher levels of antibody detected following this decline (Figure 3). Viraemia was detectable only in populations consisting of pigs that were 19 and 24 weeks of age (Figure 4). The 19–week–old pigs were viraemic but did not have antibody levels suggestive of seroconversion.


Figure 3. Characterisation of the porcine circovirus type 2 (PCV2) antibody profile of the Kansas State University (KSU) Swine Teaching and Research Center herd prior to implementation of a circovirus vaccination programme.
At the KSU farm, a total of 141 pigs were sampled across five growing pig populations (four, nine, 14, 19 and 24 weeks of age) using a cross-sectional design. Serum samples from individual pigs were tested by the Kansas State University Veterinary Diagnostic Laboratory PCV2 indirect fluorescent antibody (IFA) assay for detection of PCV2 antibodies. All IFA titres were log2 transformed to approximate a normal distribution prior to descriptive analysis. Resulting transformed means were transformed back to the original scale for presentation as geometric mean titres (GMT).


Figure 4. Characterisation of the porcine circovirus type 2 (PCV2) infection profile of the Kansas State University (KSU) Swine Teaching and Research Center herd prior to implementation of a circovirus vaccination programme.
Serum was pooled (KSU: 27 pools) within age group and analysed using the Kansas State University Diagnostic Laboratory PCV2 PCR assay for detection of PCV2 nucleic acid. Pooled results were log10 transformed and transformed results were averaged within age ranges to characterise patterns for viral load.

Phase 2

After introduction of circovirus vaccination, PCV2 PCR testing of serum samples collected over time from nine MSU and 10 KSU cohort groups showed a different infection pattern on each farm compared with baseline PCR profiles. From the MSU farm, PCV2 PCR testing on sera collected from 86 barrows at four sampling points (pre–vaccination, entry–to–finishing, mid–finishing and end–of–finishing) failed to detect PCV2 nucleic DNA (Table 1).


From the KSU farm, testing by PCV2 PCR on serum samples from 111 barrows failed to detect nucleic acid (PCV2 PCR negative) in samples collected at any time from pigs in groups 1, 2, 4, 7, 8, 9 and 10 (Table 2). Serum samples with detectable PCV2 DNA (PCV2 PCR positive) were found in group 3 (10 per cent, 1/10 samples from mid-finishing), group 5 (25 per cent, 3/12 samples from weaning; 25 per cent, 3/12 samples from entry-to-finishing; 8.3 per cent, 1/12 samples from mid-finishing; and 8.3 per cent, 1/12 samples from end-of-finishing), and group 6 (8.3 per cent, 1/12 samples from entry-to-finishing). For serum samples with detectable DNA, viral template quantity ranged from 5 to 379 viral template copies per reaction. In only 1 (group 5) of the 10 groups (10 per cent) did a pig remain viraemic for longer than one testing interval. Overall, no PCV2 viral DNA was detected in samples from seven of the 10 groups (70 per cent) monitored over a time period of greater than one year.


Phase 3

After two years of vaccinating growing pigs against PCV2 at the KSU farm, sub–samples of pigs were allocated to a circovirus-vaccinated treatment or a non–vaccinated control treatment in a growth and PCV2 antibody follow–up study (Phase 3). An interaction (P<0.001) between treatment and time occurred for antibody level (Table 3). With the exception of the initial bleed (day 0; during the weeks of weaning) when control and vaccinated pig antibody levels were similar (P=0.41), vaccinated pigs had increased (P<0.001) PCV2 antibody levels than the controls at all other sampling times.

The magnitude of the antibody responses varied over time for control and vaccinated pigs, as did the pattern of antibody production or decay. By the time the pigs were placed into the finisher, control pig antibody levels had declined (P<0.001) compared with their respective day 0 levels. However, control pig antibody levels remained similar (P=0.61) throughout the finishing period. In contrast, compared with their respective day 0 antibody levels, vaccinated pigs had an increase (P<0.001) in PCV2 antibody titre by the time of entering the finisher, which decreased (P<0.001) by each of the subsequent sampling points.

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During the nursery and grower periods, vaccinated pigs had decreased (P=0.005; Table 4) average daily gain compared with non-vaccinated control pigs. Vaccinated and control pigs had similar (P=0.30) finishing average daily gain, although growth rates for vaccinated pigs continued to be numerically less than control pig growth rates. Overall, a tendency (P=0.07) was observed for vaccinated pigs to have decreased average daily gain than the control pigs. These growth rate differences resulted in control pigs entering the finisher 2.6lb heavier (P=0.03) than vaccinated pigs. When pigs were taken off test at the end of the finishing period, control pigs had a numerical weight advantage (P=0.16) of 4.4lb over vaccinated pigs.

Phase 4

Results obtained from the commercial farm with a one–year history of circovirus vaccination differed from those observed in the KSU farm. From a serial sampling of 85 non-vaccinated sentinel pigs, no PCV2 DNA was detected in the weaning pools (0/17 pools; Table 5). In contrast, PCV2 nucleic acid was detected in pooled samples at each of three subsequent sampling ages (4.9 to 6.3 weeks of age: 1/17 pools; 7.9 to 9.3 weeks of age: 6/16 pools; and 10.9 to 12.3 weeks of age: 12/16 pools). Genotype was reported for each pool. PCV2a was detected in all but one pool (4.9 to 6.3 weeks of age: 1/17 pools; 7.9 to 9.3 weeks of age: 6/16 pools; and 10.9 to 12.3 weeks of age: 11/16 pools) but PCV2b was not detected in any of the pools until 10.9 to 12.3 weeks of age (2/16 pools).

Phase 5

Environmental swabbing and testing by PCV2 PCR (Figure 5) detected PCV2 DNA in samples from eight commercial nursery and eight commercial finisher barns. In contrast, the presence of PCV2 DNA was not detected by PCV2 PCR testing of environmental swab samples from the KSU farm.

Discussion

This was a first study to evaluate the effects of circovirus vaccination on viral circulation at the herd level. The study was designed to begin to evaluate the hypothesis that circovirus vaccination programmes in herds would affect viraemia and subsequent viral shedding into the environment. Over time, a reduction in environmental contamination coupled with continued use of circovirus vaccine to build immunity in growing pigs prior to viral exposure would aid derivation of PCV2-free herds.

The MSU and KSU herds and management served as models for commercial multi–site swine production systems. Based on the Phase 1 baseline testing, PCV2 was detected in both swine populations although viraemia was not increased until after the nursery period. This testing provided evidence for primarily horizontal rather than vertical transmission. Both herds had PCV2–viraemic pigs during finishing and showed evidence that pigs likely seroconverted after the documented time for onset of viraemia (Figures 1, 2, 3 and 4).

Although both farms had evident viral circulation during finishing, the MSU pigs experienced an earlier onset of viraemia than the KSU pigs. Both herds were considered good models in which to monitor the effects of circovirus vaccination long–term because baseline results from both non–vaccinated populations indicated viral presence and seroconversion–supporting antibody profiles.

Circovirus vaccination programmes were started in each herd in the spring of 2007, and monitoring of barrows from each farrowing group began. In the MSU herd, viraemia was not detected in serum collected at any sampling point from circovirus–vaccinated barrows (Table 1). During the same time, there were no reports of clinical PCVD from the farm but some pigs may have become transiently viraemic between sampling points. However, the MSU farm baseline testing indicated onset of viraemia early in the finishing phase and infection appeared to be detectable in a portion of the population throughout finishing. Thus, the MSU vaccinated pig PCR data demonstrate that vaccination had an effect on the viral circulation within this farm by either shortening the duration of viraemia or preventing it altogether.

In the KSU herd, three groups had at least one pig with detectable PCV2 DNA in the serum. These groups (3, 5 and 6; Table 2) were not consecutive groups, nor were the ages at the time of detectable viraemia consistent among groups. In addition, only one group had pigs testing positive for PCV2 at more than one sampling point. Although the viral load levels between sampling points were not known, the PCV2 viral loads detected in the positive serum samples among the four bleeding times were 379 template copies per reaction or less. Additionally, none of the viraemic vaccinated pigs or their group-mates had been identified as PCVD suspects. Evidence of PCV2 problems was restricted to PCR detection of transient viraemia. Although PCV2 was intermittently detected among vaccinated pigs, because no naïve pigs were in the population, the virus was not able to transmit readily, propagate within groups and establish widespread infection within the herd; therefore, the KSU herd results indicate immunisation by circovirus vaccination affected viral circulation by controlling the spread of virus and shortening the duration of viraemia or by preventing the infection entirely.

The follow-up study (Phase 3) was performed at the KSU farm to verify that circovirus vaccination had affected within-farm viral circulation patterns and to determine the farm’s new PCV2 status. Results indicate a change in the herd PCV2 antibody profile. Pigs for this follow-up study were born primarily from dams that were vaccinated against circovirus as weaned pigs. However, gilts or sows were not vaccinated against circovirus prior to breeding or during gestation. Before vaccine introduction into the herd, pigs had antibody decay until mid–finishing, followed by high levels of antibody in late–finishing so the pattern after two years of continuous vaccination was different. Antibody levels at the time of weaning were similar and low for pigs assigned to the control or vaccinated treatments (Table 3).

After vaccination, vaccinated pigs had a rise in antibody by the beginning of the finishing period that then decreased throughout finishing. In contrast, control pigs had decay in antibody levels through the beginning of finishing and never had a rise in antibody levels. The lack of antibody rise suggests that control pigs were not exposed to the PCV2 virus during the time period for sampling. Residual PCV2 virus shed from previously infected pigs and present in the environment did not appear to stimulate an immune response in these control pigs, nor did it appear that there was exposure to PCV2 virus transmitted from vaccinated but infected pigs within the groups. These follow–up KSU results indicate that the virus had either been eliminated from the herd and farm facilities, or had fallen below the threshold that could trigger stimulation of the immune system.

Growth rate has been used as an indicator of disease and was, therefore, included as a response for this study. In the study, circovirus vaccination negatively affected growth rate during the nursery and grower periods (Table 4). This resulted in vaccinated pigs 2.6lb lighter than non–vaccinated control pigs at the beginning of the finishing period.

During the finisher phase and for the overall study, vaccinated pigs had numerically reduced average daily gain compared with control pigs. At the time pigs were taken off test, control pigs had a 4.4lb numeric weight advantage compared with vaccinated pigs but the lack of positive growth rate response due to vaccination may be explainable by low or no natural PCV2 challenge in the KSU herd.

Vaccinated pigs during finishing did not demonstrate greater average daily gain than non-vaccinated control pigs. Vaccinated pigs were not able to compensate for or overcome the negative effects of vaccination in the nursery. Thus, the immunity built in the nursery and grower period did not provide any benefit during finishing because PCV2 was not present as a challenge to the immune system of the pigs. Therefore, the lack of serologic evidence for PCV2 exposure coupled with the tendency for vaccinated pigs to have poorer overall growth performance than control pigs suggests that PCV2 was not a pathogenic threat for growing pigs in the KSU herd during the follow–up testing.

The results that indicated PCV2 was no longer an apparent natural challenge for pigs in the KSU farm could not be replicated in a commercial farm in Kansas despite both farms having implemented long-term circovirus vaccination programmes. At the time the data were collected, the commercial farm had been continuously vaccinating pigs for one year – slightly less time than the KSU farm. Clinical disease had decreased during the time the vaccine was being used in the commercial herd. The commercial farm moved pigs all–in, all–out from their nursery and finisher rooms and used a disinfectant similar to that of the KSU farm. However, the period of downtime between batches of pigs for cleaning and disinfection of rooms was longer at the KSU farm than for the commercial farm.

On the commercial farm, the non–vaccinated pigs did become viraemic after movement into the nursery (Table 5) and exhibited clinical signs of PCVD. The clinical disease in these pigs was apparent even though they constituted a relatively low percentage of the population, and herd immunity did not appear to prevent propagation of the infection. Therefore, the belief that housing environment contributed a significant source of PCV2 virus in this population led the researchers to perform the environmental evaluation. They acknowledge that pig–to–pig transmission from viraemic pigs could also play a role in the dynamics of the infection but they believe this was less likely. At each time point, more serum pools had detectable DNA, which indicated that more pigs were becoming infected. In addition, PCV2a was detected first, followed by PCV2b, so the infection profile also changed over time. Whether this differential pattern has biological significance is yet to be determined.

To understand why non-vaccinated pig results differed between the KSU herd and the commercial farm, it was important to identify sources of viral exposure. Pigs at both farms were seemingly weaned free of PCV2, implicating PCV2 in the environment as a primary source of exposure. Swabs were collected in all nursery and finishing rooms at the commercial farm. Nursery and finishing rooms at the KSU farm that had housed study pigs at some point through the three–year study were also sampled. Although PCR detection of PCV2 nucleic acid does not provide any information about whether the viral material is infectious, it does allow measurement of environmental viral loads that could potentially contain infectious material.

In the commercial facility, PCV2 DNA was found in every room and barn. In contrast, at the KSU farm, PCV2 nucleic acid was not detected in either the nursery or finishing facility. Although the infectivity status of the PCV2 DNA detected at the commercial site was unknown, any residual infectious material present in the environment could explain why non-vaccinated pigs placed in this facility became viraemic shortly after movement into the facility. Complete inactivation of PCV2 was difficult by disinfection under laboratory conditions.14 Therefore, in our study, with viral material detected in the environment, some infectious virus likely remained. Further investigation of this environmental virus-based route of transmission is warranted to determine the importance of this potential risk.

In conclusion, results from this three–year investigation indicate that circovirus vaccination did affect viral circulation in swine herds. Success in lowering levels or eliminating the virus as a pathogenic threat was achieved at a university research herd but other exposure risk factors, such as residual PCV2 in the environment, appeared under commercial conditions and inhibited viral elimination efforts. Therefore, circovirus vaccine provides a tool to affect viral circulation on farms but needs to be used in conjunction with other management practices to eliminate PCV2 from most swine populations.

References

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11 Kixmöller, M., M. Ritzmann, M. Eddicks, A. Saalmüller, K. Elbers and V. Fachinger. 2008. Reduction of PMWS-associated clinical signs and co-infections by vaccination against PCV2. Vaccine 26:3443–3451.
12 Fort, M., M. Sibila, A. Allepuz, E. Mateu, R. Roerink, and J. Segalés. 2008. Porcine circovirus type 2 (PCV2) vaccination of conventional pigs prevents viraemia against PCV2 isolates of different genotypes and geographic origins. Vaccine 26:1063–1071.
13 Fort, M., M. Sibila, E. Pérez-Martín, M. Nofrarías, E. Mateu and J. Segalés. 2009. One dose of a porcine circovirus 2 (PCV2) sub-unit vaccine administered to 3–week–old conventional piglets elicits cell mediated immunity and significantly reduces PCV2 viraemia in an experimental model. Vaccine 27:4031–4037. 14 Royer, R.L., P. Nawagitgul, P.G. Halbur and P.S. Paul. 2001. Susceptibility of porcine circovirus type 2 to commercial and laboratory disinfectants. J. Swine Health Prod. 9:281-284.

Further Reading

- You can view the tables of data presented and other papers from the Kansas Swine Day 2011 by clicking here.

- Find out more information on Post-Weaning Multisystemic Wasting Syndrome (PMWS) by clicking here.


February 2012
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