Role of Immune Modulators in Replacement of AGPs
The Avian Immune System
The avian immune system consists of two types of immune mechanisms -- nonspecific and specific.4
Nonspecific Immune Mechanisms
Non-specific immune mechanisms consist of natural ways in which a bird resists disease. These mechanisms require special attention while designing a good health management program.
- Genetic factors. Continuous selection programs over generations have helped breeders to develop chickens that have high resistance power against certain disease organisms. As an example, some strains of chickens are genetically resistant to the lymphoid leukosis virus.
- Body temperature. Chickens maintain a high body temperature which ranges between 40.5°C – 41.5°C. This prevents a number of common mammalian disease organisms from affecting them. For example, black leg disease and anthrax of cattle are not problems in poultry.
- Anatomic features. A chicken’s skin is covered with feathers. This helps combat external injury. Disease organisms are unable to penetrate a chicken's intact body covering (skin and mucous membranes) or become trapped in the body's mucus secretions.
- Commensal bacteria. The gut of a healthy chicken has a stable microbial population. These microflorae help in preventing the disease organisms from invading and establishing themselves.
- Cilia in the respiratory tract. The trachea is lined with cilia. Cilia plays an important role in removing disease organisms and debris. While cilia help remove mild levels of dust, high levels of dust or ammonia can overwhelm the ciliary system or even render it ineffective.
These nonspecific mechanisms indicate the importance of biosecurity and good farm management to keep chicken healthy and productive.
Specific Immune Mechanisms
This is an acquired immune system, which has two components -- noncellular (humoral) and cellular components. The noncellular component includes immunoglobulins (or antibodies) and the cells that produce them. Antibodies are specific for the foreign materials (antigens) to which they attach. For example, the antibody against Newcastle disease virus attaches only to the Newcastle virus, not to the infectious bronchitis virus. The cellular component of the specific immune mechanisms includes all the cells that react with specificity to antigens except those associated with antibody production. The cells associated with this system, T Lymphocytes (T-cells), begin as the same stem cells as B-Lymphocytes (B-cells). T-cells are programmed in the thymus, whereas B-cells mature in the bursa of Fabricius.
There are two types of immunity – active immunity and passive immunity. Active immunity is defined as the process in which chicken produces its own antibodies following exposure to a foreign body such as bacteria. This process occurs when the chicken is given a vaccine or when there is field disease challenge. Active immunity is adversely affected by anything that damages the cellular or humoral immune systems. Passive immunity (maternal immunity) is the process wherein the chick receives antibodies from the hen through the egg. Maternal antibodies are present in the yolk, albumen, and fluids of the egg.
Poultry Gut Immunity
The gastrointestinal (GI) tract is an important organ for maintaining health. It has two important functions - absorbing nutrients and to act as the barrier against unwanted compounds and germs. Because of its extensive surface, the GI tract is also a major point of entry for many pathogens. The GI tract’s immune system has the major responsibility to act on known pathogens while ignoring components of food or “commensal” microorganisms that inhabit the gut. Failure to do this might result in intestinal inflammation and tissue degeneration.
The immune system in the intestines plays a major role in maintaining gut health. The inflammation due to compromised gut health if not tightly controlled can cause great damage to the intestine itself. It poses a risk to high performing poultry such as broilers that includes growth retardation, increased risk of infections, etc. Clostridia, like infections, benefit from this type of inflammation. One possible option to reduce the inflammation is to reduce the energy content and thereby decrease the inflammatory stimulus. A few AGPs were found to have anti-inflammatory action. As there is a great awareness today to reduce AGPs and/or completely withdraw AGPs, producers are actively searching for suitable alternatives.10
An immunomodulator may be defined as any biological or synthetic substance that can stimulate/suppress either innate or adaptive or both arms of the immune system. A potent immunomodulator has got many advantages over antimicrobials. Since immunomodulators do not affect directly microbes, they may avoid the problem of rapid emergence of resistance.6
Commonly Used Immune Modulators in Poultry
Direct Fed Microbials (DFMs) / Probiotics
DFMs have been used as prophylactic agents against enteric pathogens, presumably either by balancing microbiota, or by modulating host immunity, or both. The dietary B. subtilis when used in broilers as a potential growth promoter can provide beneficial effects on broiler performance and modulate host humoral and cellular immune responses to enteric pathogens.7 DFMs stimulate the immune system resulting in higher production of immunoglobulins, stimulation of macrophages and lymphocytes activity and also by augmentation of the production of γ-interferon.1 Regular and judicious use of probiotics has a striking effect on the immune system viz. stimulation of both humoral and cell-mediated immunity through enhanced production of natural interferons/cytokines, increased macrophage, lymphocyte and natural killer (NK) cell activity, up-regulated oxidative burst in heterophils, and increased immunoglobulin (IgG, IgM, and IgA). Probiotics produce a gut-stabilising effect and immune regulation, particularly through balanced control of pro-inflammatory and anti-inflammatory cytokines. Feeding probiotics could improve antibody titres against viral diseases like Newcastle disease (ND) and Infectious Bursal Disease (IBD). The use of probiotics increases the amount of IgA found in the intestinal lumen, the numbers of IgA, IgM and IgG-producing cells as well as the number of T cells in the cecal tonsils.5
Kemin’s proprietary organism Bacillus subtilis PB6 (CLOSTAT™) is found to have immunomodulatory activities. The prophylactic use of this organism has helped alleviate the intestinal inflammation in the mice model.2
Butyrate has been appreciated for its beneficial effects on the host, including trophic and anti-inflammatory effects on epithelial cells.11 The scientific study indicated that dietary butyrate supplementation can improve the growth performance in chickens under stress, moderate immune response and reduce tissue damage. It was also noticed that butyrate supplementation in the diet of broilers to be beneficial, especially in the presence of immune stress. Improvement of growth performance in poultry may be achieved, in part, through modulation of the response to immune challenge with butyrate administration.12 Kemin has a microencapsulated product, ButiPEARL™, that is a source of butyric acid with sustained release of active throughout the intestine.
Essential oils exert their mode of action mainly with their bactericidal effects. Production and secretion of endogenous digestive enzymes, modulation of the immune system, antifungal and antiviral activity have been proposed to address their effects on animal performance.3 Carvacrol, a commonly used essential oil in animals, has anti-inflammatory properties. The anti-inflammatory properties of carvacrol are dependent on its ability to reduce the production of inflammatory mediators, such as IL-1b and prostanoids, possibly through the induction of IL-10 release.8 Kemin’s Orsential™ is a combination of highly concentrated Carvacrol and Thymol.
Prebiotics are non-digestible feed ingredients that are metabolized by specific members of intestinal microbiota and provide health benefits for the host. Prebiotics are capable of modulating gut microbiota and the immune interactions in favor of chicken health.9
Ajit Singh Yadav, Exploring alternatives to antibiotics as health promoting agents in poultry – A review, http://jebas.org/Jou.Exp.Bio.Agr.Sci/Spl.Issue.BPADDT/10.18006_2016.4(3S).368.383.pdf
G. Lorenzoni , Poultry Diseases Influenced by Gastrointestinal Health - Traditional Treatments and Innovative Solutions, Nottingham University Press
Jacquie Jacob, Avian Immune System articles.extension.org/pages/65345/avian-immune-system
K. Dhama, Applications of Probiotics in Poultry: Enhancing Immunity and Beneficial Effects on Production Performances and Health - A Review, Journal of Immunology and Immunopathology Vol.13, No.1, January-June 2011: 1-19
Kuldeep Dhama, Effect of Immunomodulation and Immunomodulatory Agents on Health with Some Bioactive Principles, Modes of Action and Potent Biomedical Applications, International Journal of Pharmacology 11 (4): 253-290, 2015
Kyung-Woo Lee, Immune modulation by Bacillus subtilis-based direct-fed microbials in commercial broiler chickens; Animal Feed Science and Technology 200 (2015) 76–85
Milena da Silva Lima, Anti-inflammatory effects of carvacrol: Evidence for a key role of interleukin-10; European Journal of Pharmacology 699 (2013) 112–117
Mohsen Pourabedin and Xin Zhao, Prebiotics and gut microbiota in chickens, FEMS Microbiology Letters, 362, 2015, fnv122
Theo Niewold, Gut Health, Intestinal Innate Immunity and Performance, 25th Australian Poultry Science Symposium (APSS) 2014
Yukihiro Furusawa, Commensal microbe-derived butyrate induces the differentiation of colonic regulatory T cells, doi:10.1038/nature12721
W.H. ZHANG, Sodium butyrate maintains growth performance by regulating the immune response in broiler chickens; British Poultry Science Volume 52, Number 3 (June 2011), pp. 292—301