Marek's disease (MD) is an oncogenic, lymphoproliferative, and highly contagious disease of chickens. Its etiologic agent is the alphaherpesvirus Marek's disease virus (MDV, Gallid alphaherpesvirus 2), and it is a chronic and ubiquitous problem for the poultry industry with significant economic impact in the United States and worldwide. We have previously demonstrated that MDV attenuated by dicodon deoptimization of the UL54 gene results in reduced gene product accumulation in vitro, with reduced viral genome copy number upon infection and reduced atrophy of bursa and thymus in vivo as well. In this report we detail our attempts to use the same attenuation strategy on a meq-deleted MDV mutant, rMd5B40ΔMeq. Unlike the wild-type rMd5B40 virus the rMd5B40ΔMeq is no longer oncogenic, but infected birds experience an unacceptable amount of bursa and thymus atrophy (BTA). We produced two meq-deleted MDV recombinants with a dicodon-deoptimized UL54 (rMd5B40ΔMeq/UL54deop1 and -deop2) and tested their tendency to cause BTA and to serve as a protective vaccine. We found that, although dicodon deoptimization of the UL54 gene results in a virus that spares the infected animal from atrophy of the bursa and thymus, the meq-deleted UL54-deoptimized recombinant is also less protective than the meq-deleted virus without UL54 deoptimization, the HVT + SB1 combination vaccine, or the Rispens (CVI988) vaccine.

In this study, we investigated the natural route of infection of psittacine bornavirus (PaBV), which is the causative agent of proventricular dilatation disease (PDD) in psittacines. We inoculated two infection groups through wounds with a PaBV-4 isolate. In nine cockatiels (Nymphicus hollandicus) we applied a virus suspension with a titer of 10³ 50% tissue culture infection dose (TCID₅₀) via palatal lesions (Group P, P1–9). In a second group of three cockatiels, we applied a virus suspension with a titer of 10⁴ TCID₅₀ to footpad lesions (Group F, F1–3). In two cockatiels, the control (or “mock”) group, we applied a virus-free cell suspension (Group M, M1–2) via palatal lesions. The observation period was 6 mo (Groups P and M) or 7 mo (Group F). We monitored PaBV-4 RNA shedding and seroconversion. At the end of the study, we examined the birds for the presence of inflammatory lesions, PaBV-4 RNA, and antigen in tissues, as well as virus reisolation of brain and crop material. We did not observe any clinical signs typical of PDD during this study. We also did not see seroconversion or PaBV RNA shedding in any bird during the entire investigation period, and virus reisolation was not successful. We only found PaBV-4 RNA in sciatic nerves, footpad tissue, skin, and in one sample from the intestine of Group F. In this group, the histopathology revealed mononuclear infiltrations mainly in skin and footpad tissue; immunohistochemistry showed positive reactions in spinal ganglia and in the spinal cord, and slightly in skin, footpad tissues, and sciatic nerves. In Groups P and M we found no viral antigen or specific inflammations. In summary, only the virus application on the footpad lesion led to detectable PaBV RNA, mononuclear infiltrations, and positive immunohistochemical reactions in tissues of the experimental birds. This could suggest that PaBV spreads via nervous tissue, with skin wounds as the primary entry route.

A programmed self-destructive Salmonella vaccine delivery system was developed to facilitate efficient colonization in host tissues that allows release of the bacterial cell contents after lysis to stimulate mucosal, systemic, and cellular immunities against a diversity of pathogens. Adoption and modification of these technological improvements could form part of an integrated strategy for cost-effective control and prevention of infectious diseases, including those caused by parasitic pathogens. Avian coccidiosis is a common poultry disease caused by Eimeria. Coccidiosis has been controlled by medicating feed with anticoccidial drugs or administering vaccines containing low doses of virulent or attenuated Eimeria oocysts. Problems of drug resistance and nonuniform administration of these Eimeria resulting in variable immunity are prompting efforts to develop recombinant Eimeria vaccines. In this study, we designed, constructed, and evaluated a self-destructing recombinant attenuated Salmonella vaccine (RASV) lysis strain synthesizing the Eimeria tenella SO7 antigen. We showed that the RASV lysis strain χ11791(pYA5293) with a ΔsifA mutation enabling escape from the Salmonella-containing vesicle (or endosome) successfully colonized chicken lymphoid tissues and induced strong mucosal and cell-mediated immunities, which are critically important for protection against Eimeria challenge. The results from animal clinical trials show that this vaccine strain significantly increased food conversion efficiency and protection against weight gain depression after challenge with 10⁵E. tenella oocysts with concomitant decreased oocyst output. More importantly, the programmed regulated lysis feature designed into this RASV strain promotes bacterial self-clearance from the host, lessening persistence of vaccine strains in vivo and survival if excreted, which is a critically important advantage in a vaccine for livestock animals. Our approach should provide a safe, cost-effective, and efficacious vaccine to control coccidiosis upon addition of additional protective Eimeria antigens. These improved RASVs can also be modified for use to control other parasitic diseases infecting other animal species.

Duck hepatitis A viruses (DHAV-1, DHAV-2, and DHAV-3) are the predominant causes of duck virus hepatitis (DVH), a disease of ducklings that leads to massive morbidities, mortalities, and economic losses. As a duck-producing country, Egypt suffered lately from several attacks of DVH, despite the regular vaccination of birds. Between Spring 2016 and Summer 2018, 54 duckling flocks in the Sharkia province of Egypt were tested using the reverse-transcription PCR (RT-PCR) based on the DHAV-3D targeting primers. Of them, 27.8% (15/54) were positive. Upon retesting of positive samples using RT-PCR and duck hepatitis A virus (DHAV)-3 VP1-based primers, 33.3% (5/15) contained DHAV-3 RNA. For further analysis at the molecular level, the VP1 and the 3D genes were sequenced using the same primer sets used earlier. The phylogenetic trees confirmed that study sequences belonged to DHAV-3. However, they were displayed as a separate cluster following a geographically dependent distribution. They were also completely unrelated to the Egyptian DHAV-1-based vaccine. This was further confirmed by low nucleotide and amino acid identities in relation to this vaccine. In addition, the VP1 and 3D genes had the same phylogenetic topography. The study VP1 sequences had three unique amino acid substitutions (L59, V208 only in one strain, and C219). As far as we know, this is the first report on DHAV-3 outside Asia, particularly in Egypt. Accordingly, the vaccination strategy against DHAV should be quickly updated to avoid further dissemination of the virus. The epidemiology, pathogenicity, and evolution of DHAV-3 should be carefully monitored in Egypt.

Although poultry microbiome discoveries are increasing due to the potential impact on poultry performance, studies examining the poultry respiratory microbiome are challenging because of the low microbial biomass and uniqueness of the avian respiratory tract, making it difficult to sample enough material for microbial analysis. Invasive sampling techniques requiring euthanasia are currently used to increase microbial mass for the analysis, thus making it impossible to sample individual birds longitudinally. In this study, we compared invasive (nasal wash, upper tracheal wash, lower tracheal wash, and lower respiratory lavage) and noninvasive (tracheal and choanal swabs) respiratory sampling techniques in two independent experiments by using 4-wk-old chickens. We first established the experimental baseline of respiratory microbiota by using invasive techniques to enable reasonable comparisons between sampling methods and between experiments. Although noninvasive sampling (live-bird swabs) resulted in lower 16S ribosomal RNA gene copy numbers compared with invasive sampling, live swabs were able to detect the dominant microbes captured by invasive techniques. Nevertheless, swabs from euthanatized birds were more reflective of the microbiota captured through invasive methods than live swab. Furthermore, from two separate experiments, we also demonstrated that respiratory microbiota sampling is highly reproducible, especially in the trachea and lower respiratory tract. Our study provides new insights and perspectives on decision making when sampling and studying poultry respiratory microbiota.

The present study was designed to analyze the histologic and cytologic changes of lymphocyte homing in noninfected and duck Tembusu virus (DTMUV)-infected duck spleens. At first, we investigated the noninfected structure that facilitates lymphocyte homing. Under light and electron microscopy, results showed that sheath capillaries were located in the white pulp of the spleen, and the endothelial cells of sheath capillaries were cuboidal in shape, which is a typical characteristic of high endothelial venules. To monitor the lymphocyte homing, 5,6-carboxy fluoresceindiacetate succinimidyl ester (CFSE)-labeled lymphocytes that were intravenously injected into noninfected ducks appeared in the periellipsoidal sheaths (PELS), which proved that lymphocytes can return to the spleen through sheath capillaries. Furthermore, proteoglycans (PGs) associated with homing factors were positively observed in sheath capillaries and PELS by colloidal iron staining. This suggests that PGs are associated with lymphocyte homing. The results of the DTMUV infection experiment showed that PELS appeared vacuolized at 3 dpi. The spleen tissue gradually recovered at 5 and 7 dpi. In addition, the lymphocytes increased around sheath capillaries, and the expression of PGs in sheath capillaries increased after virus infection. Meanwhile, the gaps between endothelial cells were enlarged, and the lymphocytes were mainly in the lumen and basement membrane. In conclusion, lymphocytes could recruit into the spleen through sheath capillaries, and PGs participated and promoted the lymphocyte homing, suggesting that the unique high endothelial capillaries favor lymphocyte homing, which promotes tissue repair and antigen clearance in the duck.

Duck Tembusu virus (DTMUV), a mosquito-borne flavivirus, has been identified as a causative agent of an emerging disease in ducks. Since its first report in 2010, several clusters of DTMUV have increasingly been identified and caused outbreaks in many Asian countries. This highlights the need for improved and novel broad detection assays in order to detect all circulating clusters of DTMUV. In this study, a universal one-step reverse-transcription PCR (RT-PCR) assay targeting a highly conserved region of the NS5 gene was developed and validated for broad detection of all DTMUV clusters. The newly developed universal RT-PCR assay could specifically detect all clusters of DTMUV without cross-reactions with common duck viruses and other related flaviviruses. The assay was able to detect DTMUV as low as a 0.001 50% embryo lethal dose/milliliter. The performance of the assay was evaluated by using experimental and field clinical samples. The assay could successfully detect DTMUV in all experimentally DTMUV-infected samples and gave a higher DTMUV detection rate (36%) than the previously reported envelope-specific RT-PCR assay (30%) in field clinical samples. All the positive samples were confirmed DTMUV-positive by DNA sequencing. In conclusion, the newly developed universal RT-PCR assay exhibited high accuracy, specificity, and sensitivity in broad DTMUV detection, thus providing an improved screening assay for routine detection and epidemiologic surveillance of DTMUV.

A series of studies was carried out to determine the anticoccidial effects of a product derived from plant material sourced from Quillaja saponaria and Yucca schidigera. These plants are known to contain high concentrations of triterpenoid and steroidal saponins, substances that are known to display an array of biological effects. Battery tests involving individual Eimeria acervulina, Eimeria maxima, and Eimeria tenella infections and graded levels of a quillaja/yucca combination (QY) (0, 200, 250, and 300 ppm) were conducted. Body weight gain, coccidial lesion scores, and total oocysts per gram of feces (OPG) were used to evaluate anticoccidial effects. In addition, three floor pen trials evaluated the effects of 250 ppm QY in the control coccidial infections. The first pen trial measured the effects of 250 ppm QY, both alone and in combination with 66 ppm salinomycin (Sal), in a 2 3 2 factorial treatment arrangement. Two additional 42-day pen studies assessed the effects 250 ppm QY in birds vaccinated for coccidiosis. Data from the three battery trials indicated that at doses of 250 ppm QY or more, weight gain was improved, E. acervulina and E. tenella lesion scores were reduced, and OPG was lowered. In general, OPG was reduced by about 50% across all species by 250 and 300 ppm QY. Results of the pen study indicated that 250 ppm QY and Sal, when fed individually, reduced OPG and lesion scores and improved final performance. However, when QY and Sal were administered concurrently, further significant reductions in OPG occurred. The final performance of broilers vaccinated for coccidiosis was also improved at 250 ppm QY, as was OPG at both 21 and 28 days. Thus, at QY doses of 250 ppm or more, anticoccidial activity was evident but lacked the potency exhibited by many standard anticoccidials. When combined with either Sal or a live coccidiosis vaccine, QY improved the anticoccidial effects and performance of these anticoccidial methods.

Salmonella enterica subspecies arizonae (subspecies IIIa) is most frequently associated with reptiles but is also a bacterial pathogen of poultry, primarily of young turkeys where it induces septicemia, neurologic signs, and increased mortality. Arizonosis clinical cases in broiler chickens have recently been documented in the United States, driving the development of a rapid, molecular-based diagnostic for this subspecies. S. enterica subsp. arizonae is a genetically distinct subgroup of S. enterica, primarily diagnosed through culture followed by serotyping or biochemical identification, which are costly in both time and laboratory resources. Real-time/quantitative PCR offers rapid and sensitive detection of Salmonella sp. in laboratory and diagnostic samples; however, no such methodology exists to differentiate S. enterica subsp. arizonae from other Salmonella sp. In this study, we designed a quantitative PCR assay for S. enterica subsp. arizonae. The assay is able to differentiate S. enterica subsp. arizonae from other S. enterica subspecies, including S. enterica subsp. diarizonae (IIIb), and other non-Salmonella bacteria. Validation, including 56 different S. enterica subsp. arizonae serovars, demonstrated 100% sensitivity and 100% specificity. This assay provides a rapid diagnostic option for suspected cases of arizonosis in poultry.

Since the early 2000s, the avian influenza virus (AIV) subtype H9N2 has been widely circulating in North African countries, including Libya, Tunisia, and Egypt. For unknown reasons, H9N2 was not detected in Moroccan farms until the end of 2016, and at present, it is endemic in poultry. This study was carried out to evaluate the evolution of H9 AIVs in Morocco from 2017 to 2019. In this study, 16 H9 viruses collected from 2017 to 2019 in Morocco were isolated and sequenced. The genomic signatures and protein sequences of these isolates were analyzed. Moroccan H9 viruses were closely related to viruses isolated from African and Middle Eastern countries, and the hemagglutinin gene resembled those of viruses of G1-like lineage, and multiple mammalian host–associated mutations were detected that favor transmission from avian to mammalian hosts. Other mutations related to virulence were also identified. Our findings suggest that attention be given to the control of H9N2 influenza viruses in chickens and continuous monitoring of the prevalence and pathogenic potential of AIV H9N2 in the poultry population in Morocco.

Hydropericardium-hepatitis syndrome, a recently emerged disease of chickens, is caused by some strains of fowl adenovirus serotype 4 (FAdV-4). However, the relationship between the immune response and cytokine expression during FAdV-4 infection is largely unknown. In this study, our data showed that all chickens exhibited typical clinical signs and lesions and that the viral load was significantly increased in both the liver and thymus following FAdV-4 infection. We also found that the appearance of tissue lesions in the liver and thymus was consistent with the viral copy numbers, indicating that virus replication in systemic organs closely correlated with disease progression. In addition, the effects of FAdV-4 infection on the transcription of some avian cytokines were studied in vivo. In general, expression of the proinflammatory cytokines interleukin (IL)-2 and interferon (IFN)-α and IFN-β in the liver and thymus was strongly upregulated. Interestingly, the expression of IL-2 was the most highly upregulated. Expression of the anti-inflammatory cytokines IL-4, IL-10, and transforming growth factor (TGF)-β1 and TGF-β2, were also upregulated. Moreover, we investigated both the humoral and cellular immune responses in chickens infected with FAdV-4. Compared to those in the noninfected chickens, the antibody levels in chickens infected with FAdV-4 were significantly increased within 30 days postinfection. In addition, the ratio of CD4⁺/CD8⁺ T cells was decreased in FAdV-4-infected chickens. Taken together, these findings increase our understanding of the pathogenesis of FAdV-4 in chickens and provide a foundation for additional pathogenesis studies.

Ornithobacterium rhinotracheale (ORT) is an important bacterial pathogen of great economic significance to poultry production. This bacterium causes severe disease in chickens and turkeys worldwide. The objective of this study was to characterize ORT isolates from two different geographic locations in the United States by multilocus sequence typing (MLST). A total of 60 isolates were included in this study; 36 from California and 24 from Minnesota. All 60 isolates were confirmed to be ORT by PCR that targeted the 16S rRNA gene. The results of MLST revealed eight different sequence types (ST) of ORT. Out of these, four were novel and were assigned numbers ST-32, ST-33, ST-34, and ST-35. ST-1 was the predominant sequence type among all isolates followed by ST-9 and ST-8. Only one isolate was identified as ST-2. No significant variation was seen in STs in ORT isolated from different years. In turkeys, 76.3% (29/38) of isolates belonged to ST-1 and 7.9% (3/38) to ST-8. Of the chicken isolates, 72.2% (13/18) belonged to ST-1 and 16.6% (3/18) to ST-9. Isolates from both states showed low genetic variability. Of the 32 isolates from California, 24 (75%) were identified as ST-1 and 4 (12.5%) were identified as ST-9. The most prevalent sequence type was ST-1 (17/24) followed by ST-8 (3/24) in Minnesota. Three isolates from turkeys in Minnesota belonged to the same ST (ST-8) as the already known ORT strain RefO, which isolated from a rook in Germany in 2000. Whether this sequence type had evolved from wild birds could not be ascertained in this study.

Fowl adenovirus (FAdV) type 8b isolated from chickens with inclusion body hepatitis (IBH) in Japan from 2018 to 2019 were characterized serologically and genetically. Serologically, all isolates were well neutralized by antisera against the FAdV-8b strain, but they were not neutralized by antisera against the FAdV-8a strain. Phylogenetic analysis of the part of the hexon protein gene that includes the L1 region revealed that these isolates were all identical. They were also identical to foreign strains such as the SD1356 strain isolated in China and belonged to FAdV-8b. Furthermore, the 2018–19 Japanese IBH 8b isolates were genetically identical to the SD1356 strain by phylogenetic analysis of fiber genes, but they were different from previous Japanese 8b strains. These findings suggest that the 2018–19 Japanese IBH isolates might have been introduced from other countries.

Mycobacteriosis caused by Mycobacterium avium subsp. avium was observed in a parental loft of 70 meat-breed pigeons. It was decided to undertake treatment as the birds represented a substantial value to the owner. A multiagent therapy using azithromycin, marbofloxacin, and ethambutol was administered. After 4 mo of therapy, the desired results were not obtained. At the end of treatment, the birds were in poor general condition, with white blood cells above 20 g/L, and after clutching, 2-yr-old and older birds were euthanatized. Overall, postmortem lesions were found in 17 out of 49 necropsied individuals. Slide agglutination tests with a M. avium subsp. avium lysate were conducted in all examined pigeons. In 28 pigeons, blood count was conducted once a month during therapy, while in 24 pigeons, a tuberculin sensitivity test was conducted before the planned euthanatization. The tuberculin sensitivity test did not prove useful in the diagnosis of ill individuals. Slide agglutination yielded positive results in only four birds, all of which also had postmortem lesions. Blood count in a large number of cases allowed distinguishing between ill and healthy individuals, which was used for subsequent selection. The comparison of cultured strains with the (CCG)4-based PCR method showed the variation of M. avium isolates up to a maximum of 30%. The described case proves that the treatment of mycobacteriosis in pigeon flocks is not effective, mainly due to the high resistance to M. avium subsp. avium. In addition, therapy may contribute to an even greater increase in mycobacterial resistance to antibiotics, which may pose a potential risk to public health.

Major disease outbreaks caused by Streptococcus equi subsp. zooepidemicus seldom are reported in poultry. Besides acute septicemia, infection can result in a subacute or chronic form of disease with described mortality rates of 11% to 80%. Previously, the source of infection in poultry was linked to horses in which this bacterium can be present as an opportunistic pathogen on mucus membranes. The main route of spreading and being maintained within a poultry flock, after entering the stable, however, remains unclear. This case report describes an outbreak associated with S. zooepidemicus affecting a flock of 28 500 layer hens housed in an aviary system with free range. Besides sudden deaths, clinical signs of depression were noticed. Between 44 and 61 wk of age a total mortality of 23% was observed. Egg production dropped from 92% to 83%. Bacterial titration revealed substantial numbers of S. zooepidemicus present in the ceca of a healthy chicken. This novel finding hypothesizes that transmission of the infection within the flock might occur through the fecal route.

In two independent submissions, a 3-yr-old, dead Bourbon Red turkey tom from a zoo and a Royal Palm turkey hen from a backyard flock were submitted for necropsy. Both birds had been kept together with chickens. Findings of the necropsy of the first turkey were an enlarged and dark liver with many pale white foci and a few small white nodules, pale and enlarged spleen, prominent thymus, mottled and pale kidneys, and pale and enlarged testes. Findings of the necropsy of the second turkey were a dark and mildly enlarged liver and severely enlarged, firm, and pale kidneys. Histopathology revealed infiltration of most organs of both birds with neoplastic lymphocytes, which were uniform in the first turkey and pleomorphic in the second turkey. Immunohistochemistry with a CD3 marker identified the neoplastic lymphocytes as T cells. Marek's disease virus serotype 1 was detected with PCR in the livers of both birds, whereas PCRs for reticuloendotheliosis virus and lymphoproliferative disease virus were negative. Based on these findings, Marek's disease was diagnosed in both turkeys, which is very rare and were the first definitive cases reported in the United States. It is likely that the chickens were the source of infection.

A video received by faculty at North Carolina State University's Prestage Department of Poultry Science revealed a live parasite inside a chicken egg. The parasite was identified as an oviduct fluke (Prosthogonimus macrorchis), a trematode with a three-host life cycle: the primary host, a galliform bird, then an aquatic snail, and finally a dragonfly larva or adult consumed by the infected bird. The egg was from a “backyard flock” with access to a watercourse. No other instances of this parasite were seen in eggs from the flock. The presence of this parasite inside an egg suggests that the worms had migrated above the shell gland in the oviduct to be incorporated inside the egg. Currently, the occurrence of an oviduct fluke inside an egg in the United States is rare. Such parasites are not found in eggs from caged layers because those birds do not have access to watercourses. This case reinforces the view that parasites requiring intermediate hosts may become more common in birds reared under free-range conditions.

Necrotic enteritis (NE) is an important enteric disease affecting a wide variety of avian species, including poultry, caused by Clostridium perfringens type G and, rarely, type C. Significant economic losses can result from elevated mortality rates and poor performance, such as decreased weight gain associated with intestinal damage and impaired absorption of nutrients. Additional losses can result from elevated condemnation at the processing plant because of a high incidence of cholangiohepatitis. Nonenteric lesions associated with NE have been rarely reported. This paper describes uncommon presentations of NE in commercial chickens received by the California Animal Health and Food Safety Laboratory (Turlock and Tulare branches) between 2009 and 2018. Overall, extraintestinal lesions associated with C. perfringens were diagnosed in 25 cases of NE involving commercial broiler chickens. The extraintestinal sites most commonly affected included liver, followed by gizzard, bursa of Fabricius, gall bladder, and spleen. The etiology of these lesions, C. perfringens, was confirmed from a combination of gross, bacteriologic, microscopic, and immunohistochemical findings. The most common predisposing factors for NE identified were coccidiosis (56%, 14/25) and immunosuppressive disease agents, including infectious bursal disease virus (16%, 4/25) and fowl adenovirus group 1 (4%, 1/25). Additionally, four cases (16%) had microscopic lesions compatible with cystic enteritis, probably of viral etiology. This study describes the incidence of extraintestinal lesions of NE in chickens, underlying the role of enteric disorders and immunosuppression as major predisposing factors for the development of NE.

Necrotic enteritis (NE) is a common and costly disease of poultry caused by virulent toxigenic strains of Clostridium perfringens. Although the importance of trace minerals for intestinal integrity and health is well documented, there is little information on their role in ameliorating the effects of NE. The two studies reported here examined the effects of replacing a portion of the dietary zinc (Zn), copper (Cu), and manganese (Mn) supplied as sulfates in the control diets with metal-amino acid-complexed minerals in a NE-challenge model consisting of coccidiosis and Clostridium perfringens. In a 28-day battery study, the treatments were the following: (1) no additional Zn or Mn, unchallenged (negative control); (2) no added Zn or Mn, challenged (positive control); (3) added ZnSO₄ and MnSO₄ at 100 ppm each, challenged; (4) additional ZnSO₄ at 60 ppm, Availa-Zn at 40 ppm (Low), and MnSO₄ at 100 ppm, challenged; (5) added ZnSO₄ at 60 ppm, Availa-Zn at 60 ppm (high), and MnSO₄ at 100 ppm, challenged; and (6) added ZnSO₄ at 60 ppm, Availa-Zn at 40 ppm, MnSO₄ at 60 ppm, and Availa-Mn at 40 ppm, challenged. None of the treatments ameliorated gross lesion scores, but all reduced NE-associated mortality compared with the positive control. At 28 days, the group supplemented with Availa-Zn at 40 ppm (low) had a lower body weight than challenged groups supplemented with Zn and the negative control. In a floor pen study, the five treatment groups were the following: (1) Zn, Mn, and Cu from sulfate sources at 100, 100, and 20 ppm respectively; (2) Zn, Mn, and Cu from sulfate sources at 40, 100, and 20 ppm, respectively, plus Zn from Availa-Zn at 60 ppm; (3) Zn and Mn from sulfate sources at 40 and 100 ppm, respectively, plus Zn from Availa-Zn at 60 ppm and Cu from Availa-Cu at 10 ppm; (4) Zn, Mn, and Cu from sulfate sources at 60, 60, and 20 ppm, respectively, plus Zn and Mn from Availa-Zn/Mn at 40 and 40 ppm, respectively; and (5) bacitracin methylene disalicylate at 55 g/metric ton with Zn, Mn, and Cu from sulfate sources at 100, 100, and 20 ppm, respectively (Zoetis, Inc., Kalamazoo, MI). None of the treatments reduced lesion scores. The Availa-Zn and Availa-Zn/Mn had lower mortality than the sulfate-supplemented feed, whereas Availa-Zn/Cu and bacitracin methylene disalicylate were intermediate and did not differ from the other groups. Considering both trials together, and by using NE mortality as the discriminating factor, we found that adding Zn and Mn exceeding National Research Council requirements reduced NE-associated mortality, and in the floor pen study, complexed Zn and complexed Zn plus Mn appeared to be superior to sulfates.

This study investigated the effects of a proprietary commercial feed additive (FA) comprised of a blend of fatty acids, organic acids, and phytochemicals; a hydroxychloride copper (MA); as well as a water acidification product (WA), alone and in combination, on growth performance in nonvaccinated broiler chickens raised in an antibiotic-free production system. The test treatments were FA; WA; FA and WA combined (FA + WA); and FA, WA, and MA combined (FA + WA + MA). The efficacy of these treatments was compared with a negative control (CON) and a medicated feeding program (bacitracin, antibiotic growth promoter [AGP]). Ross 708 cockerels (n = 2376) were subject to a 3-phase commercial feeding program, namely, starter (0–20 days), grower (21–28 days), and finisher (28–35 days), with no coccidiostats or additional medications added to the feed. On day 14, birds were subjected to an in-feed Clostridium perfringens challenge and a subset of animals were euthanized and the ileal digesta was collected for C. perfringens enumeration. Prior to pathogen challenge (day 14), birds fed the FA + WA and F + WA + MA treatments had significantly higher body weights (+2.6%–3.5%) than those fed CON and similar body weights to birds fed the AGP. These early growth advantages were not sustained postchallenge. Clostridia counts in ileal digesta were dramatically reduced in birds fed the AGP compared with all treatments. The FA (–2.5 log), FA + WA (–2.0 log), and FA + WA + MA (–2.3 log) treatments had significantly lower clostridia counts than the CON treatment. Together, these findings support the use of combined in-feed and in-water strategies for reducing clostridia, while maintaining growth, in antibiotic-free production systems.

Challenge models are needed to understand the pathogenesis of necrotic enteritis (NE) and provide the basis of evaluating nonantibiotic feed-additive interventions. In the category of nonantibiotic feed additives, the application of probiotics to improve intestinal health and growth performance of broiler chickens in the face of an NE challenge has been well described. However, it is crucial to evaluate the consistency of specific probiotics for mitigating the disease challenge and improving performance. Therefore, a meta-analysis of five independent research trials was conducted with the objective of evaluating the effect of Bacillus subtilis DSM 32315 (probiotic) on body weight gain (BWG), feed conversion ratio (FCR), NE mortality, and lesion score (LS) of broiler chickens challenged with NE. These independent studies were conducted in three countries (the United States, Thailand, and Finland). The statistical analysis used fixed and random effects to estimate the mean effect size (MES) of the difference between NE-challenged birds (control) and NE-challenged probiotic-fed birds and the 95% confidence interval of MES. A meta-regression was performed to evaluate heterogeneity (MES variance) among studies. The statistical analysis was performed using a robust variance estimation strategy with a SAS macro. Probiotic-supplemented birds had a significantly higher BWG (MES = 1.04, P = 0.009) and a significantly lower FCR (MES = –1.39, P = 0.020), NE mortality (MES = –1.15, P = 0.012), and LS (MES = –1.29, P = 0.045). Response variables of BWG (Q = 2.81, P = 0.560) and NE mortality (Q = 5.60, P = 0.354) did not present heterogeneity. Heterogeneity was found for FCR (Q = 10.34, P = 0.035) and LS (Q = 16.13, P = 0.001). Overall, dietary supplementation of B. subtilis DSM 32315 significantly improved BWG and reduced FCR, mortality, and LS in a repeatable large-scale manner.

Clostridium perfringens (CP) is the etiologic agent of necrotic enteritis (NE) in broiler chickens that is responsible for massive economic losses in the poultry industry in response to voluntary reduction and withdrawal of antibiotic growth promoters. Large variations exist in the CP isolates in inducing intestinal NE lesions. However, limited information is available on CP isolate genetics in inducing NE with other predisposing factors. This study investigated the ability of five CP isolates from different sources to influence NE pathogenesis by using an Eimeria maxima (EM) coinfection NE model: Str.13 (from soil), LLY_N11 (healthy chicken intestine), SM101 (food poisoning), Del1 (netB⁺tpeL^–) and LLY_Tpel17 (netB⁺tpeL⁺) for NE-afflicted chickens. The 2-wk-old broiler chickens were preinfected with EM (5 × 10³ oocysts) followed by CP infection (around 1 × 10⁹ colony-forming units per chicken). The group of the LLY_Tpel17 isolate with EM coinfection had 25% mortality. No mortality was observed in the groups infected with EM alone, all CP alone, or dual infections of EM/other CP isolates. In this model of EM/CP coinfections, the relative percentages of body weight gain showed statistically significant decreases in all EM/CP groups except the EM/SM101 group when compared with the sham control group. Evident gut lesions were only observed in the three groups of EM/LLY_N11, EM/Del1, and EM/LLY_Tpel17, all of which possessed an essential NE pathogenesis locus in their genomes. Our studies indicate that LLY_Tpel17 is highly pathogenic to induce severe gut lesions and would be a good CP challenge strain for studies investigating pathogenesis and evaluating the protection efficacy for antibiotic alternative approaches.

This study was conducted to investigate the effects of replacing in-feed antibiotics with synergistic organic acids on growth performance, health, carcass, and immune and oxidative statuses of broiler chickens under Clostridium perfringens (CP) type A challenge. Two organic acid products were tested: organic acid 1 (OA1), consisting of butyrate, medium-chain fatty acids, organic acids, and phenolics; and organic acid 2 (OA2), consisting of buffered short-chain fatty acids. Six hundred 1-day-old male Arbor Acres broiler chicks were randomly assigned to one of five treatments: Control 1, basal diet, nonchallenged birds; Control 2, basal diet, with CP challenge; antimicrobial growth promoters (AGP), basal diet supplemented with Aureomycin (chlortetracycline), with CP challenge; OA1, basal diet supplemented with OA1, with CP challenge; and OA1OA2, basal diet supplemented with OA1 and OA2, with CP challenge. Each treatment had eight replicate pens of 15 birds. The experiments lasted for 29 days. The disease challenge was performed on days 15–17, with an oral gavage of 0.5 mL of CP culture (2.0 × 10⁸ colony-forming units [CFU]/mL) for each bird. Body weights (BWs), intestinal lesion scores, immune organ indices, and serum malondialdehyde (MDA) concentrations were measured on days 19, 22, and 29, respectively, in three birds per pen. Carcass characteristics were determined on day 29. No treatment-related differences in mortality were noted before (P = 0.28) or after (P = 0.64) challenge or over the whole study period (days 0–28; P = 0.66). On day 19, the BW of Control 2 was lower than other treatments (P < 0.0001). On day 22, AGP, OA1, and OA1OA2 had higher BW than Control 2 (P = 0.001). The breast muscle yield of OA1 and OA1OA2 was higher than AGP (P < 0.05). The abdominal fat yield of OA1OA2 was lower than AGP and Control 2 (P < 0.05). On day 22, the birds fed OA1OA2 showed lower intestinal lesion scores than OA1 (P < 0.05). No treatment-related differences in immune organ (spleen, thymus, and bursa) indices were noted (P > 0.05). On day 29, the MDA concentration of OA1 and OA1OA2 was lower than those of Control 1 and AGP (P < 0.05). In conclusion, the addition of organic acids may protect broiler chickens from severe intestinal lesions and oxidative stress and may help reduce abdominal fat mass deposition. There is potential for organic acid–based products as alternatives for AGP in preventing necrotic enteritis in broilers.

The purpose of the present study was to determine whether a correlation existed between chick mortality and the presence of Clostridium perfringens alpha-toxin and NetB-toxin genes (cpa and netB) in C. perfringens recovered from litter in commercial broiler houses. Because coccidiosis predisposes chickens to necrotic enteritis, the concentration of Eimeria oocysts in these samples was measured, and the numbers were used in similar correlation analyses. Litter samples were collected at 0, 2, and 4 wk growout from six broiler farms (18 houses total) during an anticoccidial drug (ACD) control program and from nine broiler farms (23 houses total) during an Eimeria vaccine (VAC) control program. Of these, litter samples were collected from five farms during both ACD and VAC programs. The litter samples were processed for Eimeria oocyst and C. perfringens spore enumerations by standard parasitologic and microbiologic techniques. DNA was also extracted for C. perfringens DNA for PCR detection of genes coding for alpha- and NetB-toxin. A general trend during the ACD programs was a transient decrease in both Eimeria maxima and non–E. maxima (Eamipt) numbers at 2 wk growout. The pattern was slightly different during VAC with E. maxima and Eamipt levels increasing over time. Average concentrations of C. perfringens in litter were highest at 2 wk (∼10⁵–10⁶ spores/g) during ACD and at placement during VAC (∼10⁵–10⁶ spores/g). During the ACD program, a strong correlation was observed between 0 and 3-wk chick mortality and the presence at placement (0 wk) of netB (r = 0.42–0.48) or cpa (r = 0.55–0.67). A very strong correlation was observed in 0–5-wk chick mortality and the presence of netB at 4 wk growout (0.73–0.95). During a VAC program, a strong correlation was only observed between the presence of netB at placement and 0–1-wk chick mortality (r = 0.67).

Restrictions on the use of antibiotics in poultry production have increased interest in nonantibiotic alternatives to control necrotic enteritis (NE). Volatile fatty acids, and in particular butyric acid preparations, have shown potential as aids in controlling NE. Valeric acid compounds may be a new additional alternative. This series of three trials compared the effects of tributyrin, monovalerin, which is an organic acid mixture, and bacitracin in a NE challenge model consisting of challenge with coccidiosis followed by Clostridium perfringens. Trial 1 was a pen trial comparing tributyrin at 0.5 kg/metric ton continuously in the feed, a proprietary organic acid blend at 1 kg per 1000 L as a metaphylactic treatment in the water, and bacitracin in the feed at 55 g/metric ton. Tributyrin and the organic acid mixture were at least as effective as bacitracin in controlling the growth- and efficiency-suppressing effects of the NE challenge, and the organic acid mixture reduced NE lesion scores. None of the treatments reduced mortality. Trial 2 was a battery study comparing monovalerin at 1.5 kg/metric ton and bacitracin in the feed. Both interventions provided significant control of both clinical and subclinical NE, with bacitracin being slightly superior to monovalerin. Trial 3 was a pen trial comparing monovalerin at 1 kg or 1.5 kg/metric ton continuously, or 0.5 kg/metric ton from 0 to 14 days and 0.25 kg/metric ton from 14 to 42 days (variable dose), to tributyrin at the same variable-dose schedule. The higher dose of monovalerin appeared to suppress feed intake and weight gain prechallenge but also produced the lowest NE mortality and the lowest total mortality of the challenged groups. All of the treatments except the variable-dose monovalerin treatment demonstrated reductions in NE lesion scores compared with the positive challenge control group; however, they did not control mortality and had fewer effects on the performance effects of subclinical NE. Results of these studies indicate that the organic acid products monovalerin and tributyrin may be useful adjuncts to reduce NE in antibiotic-free broiler production.

Clostridium perfringens, a commensal of the intestinal tract of many animal species, has been associated with necrotic enteritis (NE), an economically significant poultry disease. Clostridium perfringens is known to survive in the environment for extended periods of time through the formation of spores. These spores have the potential to be transmitted to subsequent flocks. Persistence of a single C. perfringens strain in a broiler chicken farm environment has, however, been poorly documented. The aim of this study was to compare multiple isolates of C. perfringens collected over time in a single farm with recurrent episodes of NE. Isolates were recovered from the intestines of chickens affected with NE (2014 and 2016 outbreaks) and from healthy chickens (2017), as well as from environmental samples (2016). PCR characterization of those isolates showed that all sampling groups contained netB-positive isolates except for the environmental samples. Moreover, results showed that all environmental isolates were positive for the cna adhesin whereas other groups had lower numbers of cna-positive isolates. Biofilm formation assays showed that most of the isolates were able to form biofilm. Pulsed-field gel electrophoresis analysis showed that one clone was present in every sampling group, with the exception of the 2014 outbreak. However, one clone found in the latter group was highly similar, having 94% similarity with the persistent C. perfringens clone. This study describes for the first time the persistence of a C. perfringens strain on a broiler chicken house over a 3-yr period.