Examination of a Novel Practical Poultry Management Method to Enhance the Effect of Live Eimeria Vaccination for Conventionally Housed Replacement Layer Pullets

Research Note: Evaluating fecal shedding of oocysts in relation to body weight gain and lesion scores during Eimeria infection

Coccidiosis has been a pervasive disease within the poultry industry, with test parameters used to measure effectiveness of treatment strategies often being subjective or influenced by non-disease-related activity. Four experiments were completed, which examined several test parameters of coccidiosis, including body weight gain (BWG), lesion scores, and oocysts per gram of feces (OPG). Each experiment included at least 2 parameters for measuring coccidial infection in chickens and turkeys. In experiment 1, an inoculated control was measured against 3 anticoccidial groups, whereas in experiments 2 to 4, noninoculated and inoculated controls were compared via BWG and OPG. Lesion scores were also included in experiments 1, 3, and 4. Experiment 4 resulted in high correlation, via Pearson correlation coefficient, between BWG and OPG (r = -0.69), very high correlation between OPG and lesion score (r = 0.86), and moderate correlation between BWG and lesion score (r = -0.49). Lesion scores proved to be effective in confirming Eimeria infection, although they did not correlate well with BWG or OPG. Each parameter tended to provide more useful information when lined up with the Eimeria life cycle. Incorporation of OPG, with BWG and lesion scores, as test parameters to measure coccidiosis intervention strategies, provides a global description of disease that may not otherwise be observed with the 2 latter measurements alone.

Preliminary studies on development of a novel subunit vaccine targeting Clostridium perfringens mucolytic enzymes for the control of necrotic enteritis in broilers

Necrotic enteritis (NE) is a pervasive enteric disease responsible for large scale economic losses within the global poultry industry. The etiologic agent of NE is Clostridium perfringens (CP), an opportunistic pathogen that utilizes numerous extracellular toxins and glycoside hydrolases (GH) as key virulence and nutrient acquisition factors. Notably, some GH, mucinases, degrade components of mucin in the gastrointestinal tract as an energy source. Targeting this mechanism may serve to reduce the incidence of disease associated with CP. Two experiments were completed that evaluated mucinase vaccine targets sourced from conserved peptide sequences of carbohydrate binding module 32 of CP mucinases. In experiment 1, 37 antigen peptides were synthetically generated and used to produce hyper-immune sera, which was then evaluated for ability to obstruct CP growth in vitro. Total CFU of CP were measured at 4, 6, and 8 h incubation to determine growth rate. Peptides 4, 5, 22, 24, and 30 were selected for further in vivo testing based on conservation or the ability to inhibit CP growth by over 50% at 6 and 8 h. In experiment 2, the aforementioned peptides were conjugated to an agonistic, CD40-targetting antibody and evaluated in vivo. Broilers were given an Eimeria maxima and CP in order to induce NE and assess vaccine efficacy. Treatments included a non-vaccinated non-inoculated control, non-vaccinated inoculated control (NVIC), vaccination with peptide 4, 5, 22, 24, or 30 (VP4-VP30), or a combination of all 5 peptides (MC). There was a significant increase (P < 0.05) in the percent change in BWG relative to NVIC for vaccination with peptide 22 and MC of 18.54 and 17.43%, respectively. MC vaccinated group had the lowest lesions with a mean score of 0.63 ± 0.18. These results suggest the MC combination was the most successful in alleviating overall performance losses associated with NE-infected broilers and encourage future testing of MC in the development of an NE vaccine.

Live Eimeria vaccination success in the face of artificial non-uniform vaccine administration in conventionally reared pullets

Live Eimeria vaccines against coccidiosis in poultry initiate immunity using a vaccine dose containing few oocysts; protection is enhanced through subsequent faecal-oral transmission ("cycling") of parasites in the poultry house. Spray-administered Eimeria vaccines can permit wide variations in doses ingested by individual chicks; some chicks may receive no primary vaccination at all. Consequently, protective immunity for the entire flock depends on successful environmental cycling of vaccine progeny. Pullets missing primary vaccination at day of age can become protected from coccidial challenge through cycling of vaccine progeny oocysts from vaccinated (V) cage mates. This study tested whether 40% cage floor coverage (CFC) with a durable material could improve protection against challenge in these "contact-vaccinated" (CV) or successfully V pullets. The six treatment groups tested were CV, V or sham-vaccinated pullets cage-reared on either 0% or 40% CFC. Oocyst output was measured separately for each group for 30 days following vaccine administration. Lesion scores, body weights and total oocyst outputs were measured to quantify protection at 30 days of age against single or mixed Eimeria species challenge infections. Use of 40% CFC to promote low-level oocyst cycling impacted the flock in two ways: (1) more uniform flock immunity was achieved in the 40% CFC (CV similar to V pullets) compared with 0% CFC and (2) protection was enhanced in the 40% CFC compared with the 0% CFC. The use of CFC is an easily adopted means of improving live Eimeria vaccination of caged pullets.

Shedding of live Eimeria vaccine progeny is delayed in chicks with delayed access to feed after vaccination

Hatching, processing and transportation result in inevitable delays before chicks are placed into brooding and receive their first feed and drinking water after hatching. To determine if delayed access to feed for different durations following live Eimeria vaccination affected initial shedding of vaccine progeny, replacement layer chicks (480, Lohmann-LSL Lite) aged approximately 6h after hatch were administered a commercial live Eimeria vaccine. Vaccinated chicks were divided randomly into groups and were provided access to feed immediately (0 h) or after a delay of 6, 12, or 24 h (4 treatments × 6 replicates per treatment × 20 pullets per replicate). All pullets were provided drinking water immediately following vaccination. Fecal oocysts shed per gram of feces for each cage replicate was determined daily from 4 to 9 days post inoculation. Chicks provided feed immediately had peak oocyst shedding at 5 days post-inoculation but delayed access to feed for 24h was associated with a 2 days delay in peak oocyst shedding to 7 days post-inoculation. Chicks with delays in access to feed of intermediate duration (i.e. 6 or 12h) had peak oocyst shedding at 6 days post-inoculation. Overall oocyst shedding was not affected. Live Eimeria vaccination success may be measured by evaluating initial shedding of oocysts at some pre-established time after vaccine application, usually by a single fecal collection conducted at 5, 6 or 7 days post-inoculation. Recognizing that withholding feed following live Eimeria vaccination shifts the time of the resultant peak oocyst shedding complicates the assessment of vaccine application; if delayed access to feed is not taken into account, it is possible that false conclusions could be drawn regarding the relative success of vaccine administration.

Re-description of a genetically typed, single oocyst line of the turkey coccidium, Eimeria adenoeides Moore and Brown, 1951

The Guelph strain of Eimeria adenoeides was obtained from a commercial turkey flock in Ontario, Canada, in 1985. Single oocyst derived lines of E. adenoeides were propagated, and one of them used to re-describe biological and morphological features of E. adenoeides in the turkey. Oocysts of this strain are within the lower size ranges in the original species description reported by Moore and Brown (1951); oocysts of the Guelph strain averaged 18.7 ± 1.4 μm (16.7-22.5) by 14.3 ± 0.9 μm (13-16.2, n = 30) with a shape index (SI) of 1.3 ± 0.1. It is possible that the original species description was based, at least in part, on a mixed culture of two or more Eimeria species. Immature first-generation meronts of E. adenoeides Guelph strain were observed histologically at 32 h post-infection in the ileum and cecal neck. Early studies reported only two asexual generations suggested that first asexual cycle observed at 32 h post-infection was overlooked. In the present study, three asexual generations were observed before the start of gametogony. The Guelph strain is also characterized by a prepatent period of 112 h. The Guelph strain of E. adenoeides is a highly pathogenic coccidium that forms classic cecal lesions, including prominent caseous cecal cores, during moderate to severe infections. The maximum output of oocysts (1.77 × 10(7) per bird) was obtained from birds inoculated with 1 × 10(3) oocysts; maximum fecundity (1.55 × 10(5) oocyst shed per oocyst inoculated) was obtained with an inoculation of 1 × 10(2) oocysts, but fecundity dropped dramatically as the inoculation dose increased. To promote stability of the E. adenoeides species concept, neotype specimens (a parahapantotype slides series and phototype) have been designated and deposited for future reference.