The Contribution of Eimeria Coinfection and Intestinal Inflammation to Cecal Colonization and Systemic Spread of Salmonella Typhimurium Deficient in Tetrathionate Reductase or Type III Secretion Systems Salmonella Pathogenicity Island 1 or 2.

Intestinal inflammation may provide a growth advantage for Salmonella and enhance its systemic spread in chickens. Salmonella triggers intestinal inflammation in the host by using type III secretion systems (T3SS) and produces the inflammatory end product tetrathionate. In mice, tetrathionate respiration confers a growth advantage for Salmonella Typhimurium over the competitive microbiome in the inflamed intestine. Coccidia also promote intestinal inflammation and enhance Salmonella intestinal growth and systemic spread in chickens. The objective of this study was to evaluate the contribution of inflammation, induced by Eimeria spp. or Salmonella Typhimurium, to Salmonella colonization and dissemination in chickens. In addition, the fitness costs associated with defects in tetrathionate reductase and T3SS associated with Salmonella Pathogenicity Island 1 or 2 (SPI-1 or SPI-2) were evaluated in in vivo competition experiments with wild-type Salmonella strain, with or without Eimeria coinfection. One-day-old specific-pathogen-free chickens were orally inoculated with a sham inoculum or with 4 × 102Eimeria oocysts cocktail of Eimeria tenella, Eimeria acervulina, Eimeria maxima, and Eimeria mitis. At 6 days of age, birds were orally administered a 1:1 ratio of Salmonella Typhimurium wild-type and mutant deficient in tetrathionate reductase, SPI-1, or SPI-2 (108 colony forming units/bird). Ceca, livers, and drumsticks were collected at 3, 7, 14, and 42 days after Salmonella infection, for bacteriology. Intestinal inflammation was scored by histology. Significantly higher intestinal inflammation was observed in challenge groups compared with the control. However, there were no significant differences in intestinal inflammation scores between groups coinfected with both Eimeria spp. and Salmonella Typhimurium and birds infected with Salmonella alone, and Eimeria coinfection did not increase Salmonella prevalence or abundance. Contrary to mouse studies, tetrathionate reductase did not enhance Salmonella Typhimurium cecal colonization or systemic spread in chickens. SPI-1 and SPI-2 played a significant role in Salmonella dissemination and cecal colonization in chickens, respectively.

Contribución de la coinfección por Eimeria y de la inflamación intestinal a la colonización cecal y a la propagación sistémica de Salmonella Typhimurium deficiente en tetrationato reductasa o de sistemas de secreción de tipo III de islas de patogenicidad 1 o 2 de Salmonella. La inflamación intestinal puede proporcionar una ventaja para el crecimiento de Salmonella y aumentar su propagación sistémica en pollos. Salmonella desencadena la inflamación intestinal en el huésped mediante el uso de sistemas de secreción tipo III (T3SS) y produce el producto final inflamatorio, tetrationato. En ratones, la respiración con tetrationato confiere una ventaja de crecimiento para Salmonella Typhimurium sobre el microbioma competitivo en el intestino inflamado. Coccidia también promueve la inflamación intestinal y mejora el crecimiento intestinal de Salmonella y la propagación sistémica en pollos. El objetivo de este estudio fue evaluar la contribución de la inflamación, inducida por Eimeria spp. o Salmonella Typhimurium, en la colonización y diseminación de Salmonella en pollos. Además, se evaluaron los costos de aptitud asociados con defectos en la tetrationato reductasa y T3SS asociados con las islas de patogenicidad 1 o 2 de Salmonella (SPI-1 o SPI-2) mediante experimentos de competencia in vivo con cepas de Salmonella de tipo silvestre, con o sin coinfección con Eimeria. Pollos libres de patógenos específicos de un día de edad se inocularon por vía oral con un inóculo falso o con 4 × 102 de un coctel de ooquistes de Eimeria que incluyó Eimeria tenella, Eimeria acervulina, Eimeria maxima y Eimeria mitis. A los seis días de edad, se les administró a las aves administró por vía oral una proporción 1: 1 de Salmonella Typhimurium de tipo silvestre o tipo mutante que es deficiente de tetrationato reductasa, SPI-1 o SPI-2 (108 unidades formadoras de colonias/ave). Se recolectaron ciegos, hígados y pernas a los tres, siete, catorce y 42 días después de la infección por Salmonella, para bacteriología. La inflamación intestinal se calificó por histología. Se observó inflamación intestinal significativamente mayor en los grupos de desafío en comparación con el control. Sin embargo, no hubo diferencias significativas en las puntuaciones de inflamación intestinal entre los grupos coinfectados con Eimeria spp. y Salmonella Typhimurium y las aves infectadas con Salmonella por si sola y la coinfección con Eimeria no aumentó la prevalencia o abundancia de Salmonella. A diferencia de los estudios en ratones, la tetrationato reductasa no mejoró la colonización cecal de Salmonella Typhimurium o la diseminación sistémica en pollos. Las islas de patogenicidad SPI-1 y SPI-2 jugaron un papel importante en la diseminación de Salmonella y en la colonización cecal en pollos, respectivamente.

Comparison of the application parameters of coccidia vaccines by gel and spray.

Coccidiosis is an economically significant enteric disease caused by Eimeria species. Control of the disease is achieved through various means, including chemical anticoccidial drugs, ionophore antibiotics, and vaccination. Differences between the vaccines include the number of oocysts per dose (varying by as much as tenfold between vaccines), attenuation status of the oocysts, and the species present within the vaccine. Coccidia vaccines are typically administered via spray cabinet to day old chicks; however, a new gel-based delivery system that claims to elongate preening time and increase oocyst ingestion has been introduced and is specifically recommended for certain low dose vaccines. The purpose of this trial was to compare the application properties between high and low oocyst dose vaccines administered via gel and spray delivery systems to determine if application systems could potentially affect application success. The vaccines were mixed into gel and spray diluents per manufacturer's instructions, and samples were taken to assess how well the oocysts remained in suspension. Gel and spray application patterns were assessed by measuring the size and number of droplets applied onto a plexiglass sheet in a chick basket. Different size droplets were collected and oocyst enumeration and speciation were performed. Results show that no settling occurred after mixing in either diluent. As expected, the number of oocysts per droplet increased as droplet size of the spray administration increased but stayed constant in the uniform droplet size of gel administration. There was also a consistent number of oocysts found in each of the sections across the plexiglass sheet. Taken together, these data will aid poultry producers in deciding which delivery system will provide the best application in their production system.

Evaluation of a coccidia vaccine using spray and gel applications.

Coccidiosis is an economically significant disease of poultry caused by species of Eimeria, a parasitic protozoan. Disease can result in poor feed conversion, reduced weight gain, and can lead to the development of necrotic enteritis. For prevention of coccidiosis, poultry are commonly vaccinated with a live, sporulated oocysts mass applied with a vaccination cabinet in the hatchery. Traditionally, coccidia vaccines have been applied by coarse spray in a water based diluent, however, new technology using gel diluents has entered the US market. Gel diluents can have variable viscosities and are "dropped" onto chicks with an applicator bar. It is thought that gel droplets remain intact on the birds for longer than water based droplets, allowing more time for preening and ingestion of oocysts. In this experiment, the efficacy of a commercial coccidia vaccine applied with a water based diluent, a more viscous gel diluent, and a less viscous gel diluent was compared. Fecal samples were collected at multiple time points post-vaccination to quantify vaccine oocyst shedding. Shedding in the first cycle (days 5 to 8 post-vaccination) was related to the number of oocysts received from each application method, where the groups receiving higher doses shed more oocysts. However, a decrease in shedding was seen for the more viscous gel group in the second cycle (days 12 to 15 post-vaccination). Chickens were challenged with Eimeria maxima oocysts and 7 days post-challenge body weight gains and gross and microscopic lesions were recorded to evaluate protection levels for the different vaccine applications. All vaccinated groups appeared to be protected based on body weight gain and lesion scoring. The results of this project indicate that all vaccine applications are effective at protecting against Eimeria maxima challenge when using a proper dose of vaccine that allows for repeated oocyst cycling in the litter post-vaccination.