Evaluation and optimization of quantitative analysis methods for Clostridium perfringens detection in broiler intestinal samples to use with necrotic enteritis challenge models

Briggs, Whitney

29 September 2020

No description available.

Animal Diseases

Microbiology

Molecular Biology

Quantitative methods

qPCR

direct agar plating

Clostridium perfringens

necrotic enteritis

Development of a novel loop-mediated isothermal amplification (LAMP) assay for the rapid detection of Clostridium perfringens

Chaudhary, Deepa

09 December 2022

Clostridium perfringens (C. perfringens) causes diseases such as necrotic enteritis in poultry. Current methods for early detection of C. perfringens, including culture, and molecular techniques (PCR and qPCR), have logistical limitations in detecting pathogens on-site because they require specialized equipment and long sample preparation time. This study describes developing a highly sensitive on-site LAMP assay combined with a simple DNA extraction method to detect C. perfringens. Results showed that the LAMP assay was highly specific and sensitive with the optimal reaction conditions: 63°C for 30 mins with primer concentration of 1.2 mM FIP/BIP and 0.2 mM F3/B3. The HotSHOT method was the most convenient DNA extraction method for the on-site LAMP assay with respect to the processing time, cost, and minimal equipment requirement. Therefore, the HotSHOT DNA extraction method followed by the LAMP assay could serve as a rapid on-site molecular test for C. perfringens in the field.

Clostridium perfringens

Necrotic enteritis

LAMP

PCR and Poultry

Poultry or Avian Science

An Integrated Study on Chicken Gut Microbiome Associated with Diets and Feed Utilization Using Microarray and Illumina Sequencing

Pan, Deng

January 2014

No description available.

Animal Sciences

Microbiology

chicken

microbiome

FCR

corn

wheat

necrotic enteritis

microarray

Illumina

Impact of necrotic enteritis on the growth curve and the evaluation of test parameters for measuring coccidial infection

Chasser, Kaylin M.

27 August 2018

No description available.

Animal Sciences

necrotic enteritis

growth curve

Clostridium perfringens

coccidiosis

Eimeria

oocysts per gram

fecal shedding

Managing Poultry Gut Integrity, Immunity and Microbial Balance During Necrotic Enteritis

Khodambashi Emami, Nima

12 August 2020

Necrotic enteritis (NE) is a major enteric disease in commercial poultry and manifests itself in clinical and subclinical forms. Despite years of research, NE is still among the leading diseases with the greatest economic impact on poultry production. Subclinical forms lead to poor performance (reduced feed intake, weight gain and eventually higher feed conversion ratio) but usually occurs with low mortality rates. The use of antibiotic growth promoters (AGPs) is proving to be an effective tool in maintaining gut health and modifying gut microbiota, thus improving broiler performance and reducing NE. Removal of AGPs has led to an increase in NE occurrence, particularly the subclinical forms. The lack of alternative strategies to control NE is mainly due to limited insight into the relationship between NE pathogenesis, the host microbiome and its immune responses. Therefore, key to overcoming NE is to define the cellular and molecular mechanisms that are involved in the progression of the disease, especially with regard to mucosal immune responses and gut microbiome. Also, assessing the impact of these changes on gut cell metabolism and function is of great importance. This information would be a valuable guide to prevent the onset or alleviate the negative impact of NE on bird's health and performance. In a series of experiments conducted for this project, the effect of single or multi-strain probiotics as well as multi-component additives were tested during NE challenge in order to define the cellular and molecular mechanisms that are involved in the progression of the disease. Results of these experiments revealed that challenging broilers with a 'naturally occurring' NE led to differential expression of tight junction (TJ) proteins in the jejunum compared to non-challenged birds. Supplementation of certain additives reduced NE lesion scores, improved performance and increased mRNA abundance of claudin-3, a key epithelial TJ protein. Multi-strain probiotics and multi-component additives (including a symbiotic and a product containing probiotics, prebiotics and essential oils) were more effective than single-strain probiotics or prebiotics. The aforementioned additives were also more effective in modulating immune responses to NE, especially by decreasing the mRNA abundance of IFN-γ and IL-10 in the jejunum. Furthermore, supplementation of these additives led to an increase in the expression of nutrient transporters (SGLT-1) and regulators of energy metabolism (PGC-1α, mTOR and AMPK); thus, improving nutrients absorption and metabolism. Microbial profiling using 16S rRNA sequencing showed that supplementation of each specific additive led to a signature-like microbiome in the ileal scrapings of broilers. However, supplementation of multi-component additives (including a symbiotic and a product containing probiotics, prebiotics and essential oils) modified the ileal microbiome in association with lower NE lesion scores, better performance and modulated immune responses. These additives reduced the relative abundance of bacteria such as ASF356, Bacteroides, Clostridium sensu stricto 1, Faecalibaculum, Lachnospiraceae UCG-001, Muribaculum, Oscillibacter, Parabacteroides, Rikenellaceae RC9 gut group, Ruminococcaceae UCG-014, and Ruminiclostridium 9 and increased the relative abundance of Lactobacillus compared to NE challenged birds. Collectively, these data indicate that during a subclinical naturally occurring NE, the use of multi-strain probiotics or multi-component additives, compared to single-strain probiotics or prebiotics, would be a more promising strategy in alleviating the effect of this enteric disease. / Doctor of Philosophy / Necrotic enteritis, an enteric disease, is one of the major diseases that negatively impacts the poultry industry and producers' profitability. The growing ban on the use of antibiotics that were used to prevent this disease has increased the number of necrotic enteritis outbreaks worldwide. Having a better understanding of the cellular and molecular mechanisms that are involved in the onset of this disease is of crucial importance and could lead to finding more effective ways to control this disease without drugs. The gut is the site of digestion and absorption of nutrients so any damage would lead to poor bird performance. In a series of experiments conducted for this project, several combinations of beneficial bacteria and nutrient sources that help bacterial growth in the gut (prebiotics) improved gut health leading to better performance during the grow-out period (days 0-42) when birds reach market age. These supplements protected the gut lining and reduced damages due to necrotic enteritis with less severe lesions. Barrier function of the gut was also improved by supplementing the diet with combination of beneficial bacteria and nutrients that help their growth in the gut. There are special types of proteins (called tight junctions) that seal up the space between intestinal cells (enterocytes) and prevent pathogens in the gut lumen from entering the body, thus preventing inflammation and disease. This helps the body to use the absorbed nutrients for growth rather than spending energy to fight pathogens, which collectively results in better growth performance. Concurrent supplementation of beneficial bacteria plus nutrients that help their growth balanced the immune responses in the gut by increasing the copy number of cytokines. Cytokines are proteins that orchestrate immune responses that the host mounts against pathogens. Certain cytokines regulate such responses by preventing the immune system from overreacting and mounting unnecessary reactions, thus preserving energy and nutrients for growth while reducing inflammation. Nutrient uptake from the gut lumen is facilitated by nutrient transporter proteins that reside on intestinal cells (enterocytes). Birds concurrently supplemented with beneficial bacteria and nutrients that help their growth in the gut increased the abundance of these proteins, resulting in improved nutrient uptake and performance compared to the control birds. Co-supplementation of beneficial bacteria and nutrient sources that help their growth modified the type and number of bacteria that are present in the gut lumen. The modified bacterial community were able to produce metabolites such as butyrate and propionate, which are beneficial for the health and growth of the intestinal cells, thus improving the bird's health and its performance. Overall, compared to beneficial bacteria alone, co-supplementation of beneficial bacteria with the nutrients that help their growth in the gut significantly reduced intestinal lesions and improved performance of broiler chickens during the production period. Moreover, dietary addition of these supplements improved gut barrier function by regulating the gene expression of tight junction proteins and gut mucosal immune responses as well as modifying the bacterial community of the gut. Therefore, such combination supplements hold promise in controlling necrotic enteritis in poultry and sustain good overall performance that translates into higher profitability to producers.

necrotic enteritis

Performance

lesion scores

tight junctions

immune response

gut microbiome

In ovo and feed application of probiotics or synbiotics and response of broiler chicks to post-hatch necrotic enteritis

White, Mallory Beth

04 June 2021

Immediately post-hatch, broiler chicks are exposed to microbes that begin colonizing the gut, including environmental pathogens. One of the costliest enteric diseases in broiler production is necrotic enteritis (NE), caused by the ubiquitous opportunistic bacteria Clostridium perfringens (CP). With the worldwide reduction in antibiotic growth-promoters (AGPs), there is increased interest in natural alternatives to reduce disease and improve broiler health. The overall objective of the studies described herein was to apply probiotics or synbiotics to birds by in ovo application or orally before they leave the hatchery, then evaluate bird performance and various intestinal responses. Data were analyzed in JMP with LS Means to separate means with significance assigned at P ≤ 0.05 and trends at 0.05 < P ≤ 0.10. The first 21-day (D) study used 480 male Cobb 500 broilers randomly divided into one of four treatments using a 2x2 factorial design: a no-additive control (CTRL), a one-time oral application of synbiotic at the hatchery fed a basal diet (HS), an oral application of water at the hatchery with dietary synbiotics (DS), and a hatchery synbiotic plus dietary synbiotic (HSDS). Performance was measured on day-of-hatch (DOH), D3, D7, D14, and D21. mRNA abundance of various intestinal markers was measured at D7 and D21, including tight junction proteins ZO-1, ZO-2, and CLD-1; nutrient transporters SGLT1 and PepT1; and immune response markers TLR2, TLR4, and IL-10. HS lowered feed intake (FI) and feed conversion ratio (FCR) without lowering body weight (BW) from D14-21. There was greater abundance of PepT1 mRNA (P ≤ 0.1) and IL-10 mRNA (P ≤ 0.05) on D21 in HSDS. Second, a 21-day pilot study with 480 male and female Cobb 500 broilers was conducted to determine the optimum in ovo dosage level of a probiotic or synbiotic (PROB or SYNB) applied at embryonic day 18 (E18) with subsequent NE challenge using seven treatments: in ovo application of sterile water (CTRL), low (PROB-L or SYNB-L: 1x105 CFU), medium (PROB-M or SYNB-M: 1x106 CFU), or high (PROB-H or SYNB-H: 1x107 CFU) probiotic or synbiotic doses dissolved in sterile water. Performance measurements were taken on DOH, D4, D8, D14 and D21. On D8, NE lesion scores were not impacted by treatment. D8 ileal samples were taken for mRNA abundance of TLR4, IL-10, IL-1β, AvBD8, AvBD10, and AvBD13. SYNB-H had higher abundance of AvBD10 mRNA compared to CTRL (P ≤ 0.1), and higher IL-1β mRNA compared to SYNB-L (P ≤ 0.05). PROB-H and SYNB-H had better performance than the low and medium doses, but were not better than the CTRL. The high doses were chosen for subsequent studies. Third, a longer 42-day study using 1,630 Ross 708 male and female broilers was conducted consisting of the following six treatments. A negative control (NC): sterile water in ovo fed basal corn/soybean meal mash diet without NE challenge; antibiotic growth-promoter (AGP+): sterile water in ovo fed basal diet with virginiamycin (0.5 kg/MT) as an AGP with NE challenge; NC+: same as NC plus NE challenge; SI+: synbiotic in ovo fed the basal diet and NE challenged; SD+: sterile water in ovo fed basal diet supplemented with synbiotic (0.5 kg/MT feed) and NE challenged; and SID+: synbiotic in ovo fed basal diet with synbiotic (0.5 kg/MT feed) with NE challenge. Cumulatively, SID+ had lower FI and FCR than NC+, but no change in BW or BWG. The combination treatment (SID+) often had an additive effect compared to SD+ or SI+ alone on mRNA abundance and D7 cecal fatty acid profiles. SD+ and SID+ also had higher D42 lean:fat ratios compared to NC+. Last, a 42-day study was conducted using 1,630 male and female Ross 708 broilers and the in ovo application of probiotics and subsequent NE challenge with five treatments. NC: sterile water in ovo, fed basal corn/soybean meal mash diet without NE challenge; AGP+: sterile water in ovo, fed basal diet with virginiamycin (0.5 kg/MT of feed) as AGP with NE challenge; NC+: NC treatment, with NE challenge; PI+: probiotic in ovo, fed basal diet, with NE challenge; PD+: sterile water in ovo, fed basal diet supplemented with probiotic (1.3 kg/MT of feed), with NE challenge. The use of probiotics in this study had little effect on performance, lean:fat ratios, and cecal fatty acid profiles, but PD+ increased mRNA abundance of D14 TLR2, D14 TNF-α, and D42 LEAP2 in cecal tonsils compared to controls. PI+ increased mRNA abundance of D7 and D42 MUC2, D7 LEAP2, and D42 TNF-α in the ileum. PI+ increased mRNA abundance in the cecal tonsils of D7 TLR2 and D42 TNF-α. These studies yielded interesting results about probiotics and synbiotics during a NE challenge by evaluating performance, intestinal immune responses, and fatty acid profiles in the ceca of broilers. In conclusion, the probiotic in this study did not improve broiler health during a NE challenge, but synbiotic use in ovo and continuation in the feed showed improvement over in ovo or dietary application alone. Synbiotic improved FCR over a challenged control, and altered mRNA abundance in the small intestine. / Doctor of Philosophy / The poultry industry is one of the most popular animal protein sources worldwide. As with any livestock operation, industry goals include optimizing animal health and well-being, maximizing animal productivity, and producing quality products in the most cost effective manner. Improvements in genetics, nutrition, and management have increased productivity and cut costs. One important application was the low-level use of antibiotics in feed. These medications reduced the risk of disease outbreak in flocks, which led to healthier birds and improved growth rates. However, when global concern of antibiotic resistance in human medicine came to light, both the livestock industry and governing bodies implemented voluntary and mandatory reduction or elimination of antibiotics. Previously, these important antibiotics helped to control costly diseases. As they are removed, alternatives to antibiotics will be important in disease control and prevention. A major group of alternatives to antibiotics in poultry includes probiotics, prebiotics, and synbiotics. Probiotic bacteria are considered 'good bacteria' in the gut, and provide various health benefits to the host. Prebiotics are non-living substances that support the growth of healthy bacteria. A synbiotic is the combination of both probiotics and prebiotics in a single application method. The goal of this research project was to give probiotics or synbiotics to broiler chicks and evaluate their potential benefits and effects on bird performance and the immune response. Ideally, applying probiotic bacteria as early as possible might translate into early colonization of the gut with healthy bacteria. This included oral application of synbiotics at the hatchery, or by safely injecting them into part of the egg that is swallowed by the chick embryo before hatch. This egg application, or in ovo application, is a safe, effective, widely-practiced method of vaccinating chicks to jumpstart their defense against disease. By vaccinating them in ovo, they can start to prime the immune system before they even hatch. Applying probiotics in ovo may improve health after early gut colonization with beneficial microbes. Numerous studies on natural alternatives to antibiotics have been conducted, with varying results. Results of this research indicate that in ovo application of probiotics and synbiotics is safe. Birds that received probiotics in the feed often performed similar to those that received none. However, the in ovo use of synbiotics combined with the continued use in the feed after hatch improved efficiency in broilers during an intestinal disease challenge and improved various aspects of gut function. Overall, as antibiotics are phased out, using probiotics and synbiotics may improve poultry health, but continued research will help understand the optimum ways to use them.

probiotics

symbiotics

coccidiosis

necrotic enteritis

in ovo

Performance

mRNA

volatile fatty acids

Mise au point d'un modèle d'infection expérimentale d'entérite nécrotique clinique chez le poulet de chair par des facteurs prédisposants

Bélanger, Mathieu

January 2008

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal.

Poulet

Chickens

Entérite nécrotique

Necrotic enteritis

Clostridium perfringens

Clostridium perfringens

Modèle expérimental

Infection model

Eimeria

Eimeria

Blé

Wheat

Microflore

Microflora

Mise au point d'un modèle d'infection expérimentale d'entérite nécrotique clinique chez le poulet de chair par des facteurs prédisposants

Bélanger, Mathieu

January 2008

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal

Poulet

Chickens

Entérite nécrotique

Necrotic enteritis

Clostridium perfringens

Clostridium perfringens

Modèle expérimental

Infection model

Eimeria

Eimeria

Blé

Wheat

Microflore

Microflora

Identification et caractérisation des bactériocines de souches commensales de Clostridium perfringens

Deslauriers, Nicolas

08 1900

Travail en codirection avec M. Frédéric Raymond / Avec la présente augmentation de la résistance aux antibiotiques et l’inquiétude des consommateurs, de nouvelles alternatives sont nécessaires afin de contrôler l’entérite nécrotique (EN), une maladie causant des millions de dollars en pertes économiques pour l’industrie de la volaille mondialement. Les bactériocines sont des peptides antimicrobiens produits par une bactérie pour tuer ou inhiber la croissance d’autres compétiteurs bactériens. La perfrine est la seule bactériocine reportée associée aux souches pathogènes de Clostridium perfringens, l’agent causal de l’EN. Les objectifs de cette étude étaient de détecter les souches commensales de Clostridium perfringens possédant une activité antimicrobienne contre des souches pathogènes de C. perfringens et d’identifier et caractériser les bactériocines produites. Les souches commensales de C. perfringens ont été sélectionnées à partir de notre banque de souches. L’activité antimicrobienne de ces souches a été testée contre des souches pathogènes de C. perfringens en utilisant la méthode d’inhibition sur gélose. Une souche commensale active démontrant une activité antimicrobienne a été cultivée et ses bactériocines ont été partiellement purifiées grâce à la précipitation au sulfate d’ammonium et par chromatographie (HPLC). À la suite de chaque chromatographie, l’activité antimicrobienne des fractions a été vérifiée en utilisant la méthode décrite précédemment afin de choisir les fractions contenant les bactériocines. La susceptibilité enzymatique, la stabilité à la chaleur et au pH et le poids moléculaire estimé des bactériocines ont été caractérisés. Les bactériocines étudiées étaient sensibles à la protéinase K, thermolabiles, stables à pH entre 4 et 8 et leur poids moléculaire étaient supérieur à 30 kDa. Le génome de la souche CP1676 a été séquencé et des analyses bio-informatiques ont été réalisées. Nous avons trouvé 28 séquences de bactériocines potentielles, mais seulement 4 d’entre elles semblaient être prometteuses. Dans cette étude, des souches commensales de C. perfringens produisant des bactériocines actives contre des souches pathogènes ont été identifiées. Ces bactériocines pourraient devenir une alternative intéressante aux antibiotiques afin de contrôler l’entérite nécrotique, mais davantage d’information est nécessaire. / With the current increase in antimicrobial resistance and consumers’ concern, new alternatives are needed to control necrotic enteritis (NE), a disease that causes billions of dollars in economic losses to the poultry industry worldwide. Bacteriocins are antimicrobial peptides produced by bacteria to kill or inhibit the growth of other bacterial competitors. Perfrin is the only reported bacteriocin associated with pathogenic strains of Clostridium perfringens, the causal agent of NE. The aims of this study were to screen for commensal Clostridium perfringens strains with an antimicrobial activity against C. perfringens pathogenic strains and to identify and characterize the produced bacteriocins. Commensal C. perfringens strains were selected from our bacterial collection. Antimicrobial activity of those selected strains was tested against C. perfringens pathogenic strains using the agar spot test method. An active commensal strain showing antimicrobial activity was cultured and its bacteriocins were partially purified using the ammonium sulfate precipitation method and HPLC. After each chromatography, antimicrobial activity of fractions was tested using the method described above to choose fractions containing bacteriocins. Enzyme susceptibility, heat and pH stability and the estimated molecular weight of the bacteriocins were characterized. The studied bacteriocins were sensitive to proteinase K, thermolabile, stable at pH between 4 and 8 and their molecular weight higher than 30 kDa. CP1676 strain genome was sequenced and bioinformatics were performed. We found 28 potential bacteriocin sequences, but 4 of them seemed to be promising. In this study, commensal C. perfringens strains producing bacteriocins active against pathogenic strains have been identified. These bacteriocins could be an interesting alternative to antibiotics for the control of necrotic enteritis but further data is still needed.

bactériocines

Clostridium perfringens

entérite nécrotique

purification

caractérisation

bacteriocins

necrotic enteritis

characterization

Prevalence and molecular characteristics of avian pathogenic Escherichia coli and Clostridium perfringens in 'no antibiotics ever' broiler farms

Fancher, Courtney

30 April 2021

Avian pathogenic Escherichia coli and Clostridium perfringens cause economic and welfare concerns to the broiler industry. The recent shift to no antibiotics ever (NAE) production has increased disease incidence. The objectives of this study were to determine the influence of season, age of flock, and sample type on E. coli prevalence and virulence and to identify C. perfringens prevalence and toxinotypes in NAE farms. Results indicated high prevalence of virulent E. coli; prevalence of virulent E. coli decreased from Spring to Summer. Virulent E. coli showed high resistance to antimicrobials. Serogroups O8 and O78 were most prevalent in virulent E. coli. C. perfringens prevalence was very low and all recovered isolates were toxinotype A with variation in netB, cpb2, and tpeL presence. In conclusion, NAE farms should have measures to control E. coli infections, especially in spring season. Further studies are required to confirm the lower prevalence of C. perfringens.

Escherichia coli

Clostridium perfringens

broiler

chicken

antibiotic resistance

necrotic enteritis

colibacillosis

no antibiotics ever

avian pathogenic Escherichia coli