E-ISSN 2146-9369 | ISSN 2146-3158
 

Review Article


J. Microbiol. Infect. Dis., (2024), Vol. 14(3): 95–102

Review Article

10.5455/JMID.2024.v14.i3.2

Chicken immunoglobulin as an alternative treatment for bacterial infections, emphasizing advantages, disadvantages, and mechanisms

Zahra Esmaeili1,2, Sara Kamal Shahsavar1,2, Masoud Keikha3 and Kiarash Ghazvini1,2*

1Department of Microbiology and Virology, School of Medicine, Mashhad University of Medical Sciences, Mashhad, Iran

2Antimicrobial Resistance Research Center, Mashhad University of Medical Sciences, Mashhad, Iran

3Department of Nursing, School of Nursing and Midwifery, Iranshahr University of Medical Sciences, Iranshahr, Iran

*Corresponding Author: Kiarash Ghazvini. Department of Microbiology and Virology, School of Medicine, Mashhad University of Medical Sciences, Mashhad, Iran. Email: GhazviniK [at] mums.ac.ir

Submitted: 22/06/2024 Accepted: 19/08/2024, Published: 30/09/2024


ABSTRACT

The overuse of antibiotics has led to an alarming spread of drug-resistant microbial infections, creating an urgent need for new therapeutic technologies. This issue has become a significant concern in recent years due to the increase in mortality rates, especially in hospital infections. In addition to antibiotic resistance, side effects caused by antibiotics, such as liver and kidney complications, threaten immunocompromised patients, infants, and the elderly, which indicates the need for immediate action. One of these technologies that has attracted attention as an alternative or complementary treatment for bacterial and viral infections is chicken immunoglobulin (IgY). This process involves extracting chicken immunoglobulin antibodies from egg yolk, which is achieved by injecting killed or recombinant pathogen antigens into the chicken. Several studies have investigated the therapeutic effects of IgY on bacterial infections in vitro and in vivo. However, a research gap exists regarding the mechanism of action, benefits, and possible side effects of these antibodies. This review article examines the structure, mechanism of action, optimal production conditions, advantages, and disadvantages of using this antibody, which can be widely used in the future.

Keywords: Adverse reactions, Antibody, Immunoproteins, Infection control, Therapeutic effects.


Introduction

Over a century ago, the initial proof of IgY production and transfer from a mother to an egg yolk was discovered. This type of immunity can safeguard the fetus for 2 weeks. It was first considered for human use in 1999 (Klemperer, 1893; Hamal, et al., 2006; Gadde et al., 2015). IgY is an antibody found in egg yolk that can be passed from mother to fetus, similar to IgG in humans (Sunwoo et al., 2002), and found not only in birds but also in reptiles, amphibians, and even fish. Its structure is similar to that of human IgG in terms of Fab and Fc fragments and function. It can be detected in large quantities, up to 100 mg per egg yolk (Warr et al., 1995; Schade et al., 2005). Despite their structural, functional, and frequency similarities, studies have shown a closer evolutionary relationship between IgY and IgE than between IgY and IgG (Taylor et al., 2009).

This antibody can maintain stability in a pH range from 4 to 9 and at temperatures above 65°C. It also remains stable in the presence of pepsin at the mentioned pH, ensuring its protective effect is preserved. This allows it to be stored in powder form for several months, even outside the refrigerator (Wen et al., 2012; Thu et al., 2017).

IgY structure

Birds have antibodies similar to humans, such as IgA and IgM, but they also have another type of antibody called IgY. It is considered the most dominant type of antibody. Its structure is similar to mammalian IgG but lacks a hinge region. This structural difference results in a much longer half-life than IgG (Rose et al., 1974; Pereira et al., 2019). IgG and IgY are two types of antibodies that have structural differences. One of the differences is that IgY has a variable region and four constant regions, while IgG has fewer constant regions. IgY is larger with a molecular weight of 167 kDa, consisting of two heavy chains of 65 kDa and two light chains of 19 kDa. On the other hand, IgG has a smaller Fc region, making it less hydrophobic, and has a higher isoelectric pH than IgY. Finally, the molecular weight of IgY is approximately seven kDa greater than IgG’s (Sun et al., 2001). Under non-reducing conditions, its molecular weight can increase from 167 kDa to 180 kDa (Leiva et al., 2019).

IgY mechanisms

There are multiple hypotheses for this case. One method to prevent bacteria from binding to host cell surface receptors is to inhibit their interaction (Lee et al., 2002). On the other hand, the binding of IgY to bacterial surface components such as pili, flagellum, and Omps may disrupt their activity and have a reducing effect on Quorum sensing and cellular signaling (Xu et al., 2011).

Due to the importance of other neutralizing antibodies, IgY may play a role in neutralizing toxins and infections through this pathway. (Nilsson et al., 2007a,b). A study on the effect of IgY in Salmonella showed that this antibody can balance the production of inflammatory cytokines such as IFN-γ and TNF-α and modulate the immune response (Li et al., 2016). One of the direct impacts of IgY is its ability to significantly decrease bacterial growth, thereby effectively reducing pathogen growth in a dose-dependent manner (Schwartz et al., 2022). PMN cells play a crucial role in the innate immune system by controlling primary infections and inflammation (Thomsen et al., 2015). Opsonization of bacteria can be increased by factors such as IgG and complement (Joiner et al., 1984).

Previous studies have demonstrated its role in phagocytic activity. It can induce polymorphonuclear (PMN) cells through physicochemical changes in bacteria, such as increased hydrophobicity and bacterial accumulation (Keller and Stiehm, 2000; Thomsen et al., 2015).

This increase in phagocytosis by PMN cells may be due to changes in the electric charge of the bacterial surface and their interaction (Lee et al., 2002). The accumulation and clamping can change the geometry and structure of the pathogen, leading to bacterial immobilization and phagocytosis by immune cells (Champion and Mitragotri, 2006). Electron microscope investigations were conducted to study the effect of IgY on multi-drug-resistant Acinetobacter strains. The results showed that this antibody can inhibit Acinetobacter by increasing bacterial agglutination (Tsubokura et al., 1997). These findings have the potential to significantly enhance the rate of removal of pathogenic bacteria by altering the saturation of PMNs (Carlander et al., 1999a,b).

In general, mechanisms such as inhibiting bacterial attachment, increasing opsonization of pathogens by PMs, modulating immunity, and finally neutralizing toxins are more prominent. The various hypotheses mentioned above are given in Figure (1).

Optimal production and purification of IgY

Different types of antigens, such as complex (virus and bacteria) and single (protein, nucleic acid, and polysaccharide) antigens, have been used to produce specific IgY in birds (Pereira et al., 2019). Different concentrations of antigens can be combined with various adjuvants that differ in chemical properties and immune system stimulation ability (Schade et al., 2005; Kovacs-Nolan and Mine, 2012; Savoldi et al., 2018; Pereira et al., 2019).

While Freund’s complete adjuvant (FCA) is a very effective adjuvant for antibody production, it has some risks. It is known to cause severe inflammation at the injection site, which can lead to severe reactions. Unlike FCA, FIA does not contain mycobacteria and is less potent but causes fewer side effects. Therefore, it is better to use FCA for the first inoculation and switch to FIA for subsequent inoculations to minimize inflammation at the injection site (Schade et al., 2005; Kovacs-Nolan and Mine, 2012; Pereira et al., 2019). After producing the desired antigen, which can be either the complete cell form or a recombinant antigen with adjuvant, it is injected intramuscularly into the breast muscle of 6-month-old chickens. After 3 weeks of immunization, the eggs are collected. The number of required inoculations varies based on the type and dose of antigen, as well as the adjuvant used (Pereira et al., 2019). If the antibody titer decreases, more vaccinations should be administered during the spawning period to boost the antibody titer (Pereira et al., 2019).

Therefore, the success of a successful immunization depends on several variables, including the intervals between the first, second, and subsequent vaccinations (Schade et al., 2005). One pivotal factor in optimizing the production of IgY is the breed of chicken used for immunization. For instance, the Rhode Island Red chicken breed demonstrates its potential by producing almost twice the amount of antibodies as the Single Comb White Leghorns. This highlights the significant impact of breed selection on immunization outcomes (Amro et al., 2018). Long light periods can reduce acquired immunity and antibody production in chickens. Providing 6 hours of darkness daily can improve antibody production (Hofmann et al., 2020).

Recent studies have compared different methods such as water dilution, PEG, caprylic acid, chloroform, phenol, and carrageenan for the extraction and purification of IgY. The practical implications of these findings are significant. This research shows that water, PEG, and carrageenan dilution methods provide the highest yield, purity, and lipid residue, respectively. On the other hand, the chloroform method provides the highest filtration rate and protein concentration. Although water and PEG dilutions are the most commonly used methods, chloroform may be preferred in some cases (Ren et al., 2016; Shikun Ge, 2020).

The isolation of IgY antibodies can be achieved through the polyethylene glycol 6,000 precipitation method from egg yolk. The extracted antibodies can be further purified through chromatography using the SDS page and western blotting before it is confirmed (Amro et al., 2018). One of the significant challenges in preparing IgY is purification and separation from yolk lipoproteins. As a first step, the water-soluble part containing IgY is separated from the lipid part (Kovacs-Nolan and Mine 2012). Various techniques have been suggested for isolating yolk lipoproteins. These methods include the precipitation of lipoprotein by polyethylene glycol and dextran sulfate, purification by organic solvents, dilution of yolk, and centrifugation at high speeds, ultrafiltration, and usage of natural polysaccharides such as xanthan gum, carrageenan, and sodium alginate (Mine and Kovacs-Nolan 2002; Kovacs-Nolan and Mine, 2012; Siriya et al., 2013; Pereira et al., 2019).

To store this antibody for a longer duration, it can be kept in a refrigerator at 4°C for up to 5 years. However, previous studies have shown that the half-life of IgY in the gastrointestinal tract is only 1.73 hours. Therefore, it is necessary to use delivery methods like liposomes to increase the antibody’s efficiency (Yokoyama et al., 1993; Rahman et al., 2013; Li et al., 2022).

IgY advantages

Antibiotic resistance, particularly in hospital infections, has become a severe threat. For instance, some studies have reported multidrug resistance in Acinetobacter baumannii strains up to 74% (Pourhajibagher et al., 2016). IgY can potentially treat infections by reducing inflammation and mortality in vitro and in vivo against multi-drug infections (Shi et al., 2017). One of the benefits of antibodies is that they cause less SOS response in bacteria, reducing the transmission of resistance genes (Beaber et al., 2004).

Passive immunotherapy has long been recognized as a promising treatment for bacterial infections like diphtheria, tetanus, and botulism. However, its use against resistant bacterial infections like Staphylococcus aureus is also anticipated (Keller and Stiehm 2000). This type of immunotherapy was first identified in 1893 and was introduced as an acceptable treatment about a century later, i.e., in 1996 (Schade and Hlinak 1996). This antibody has a protective activity lasting 5–10 years when stored at 4°C. It can last for 6 months when stored at room temperature and up to 1 month at a temperature of 37°C. For more extended storage, it is recommended to store it at −20°C or in powdered form (Larsson et al., 1993; Staak et al., 2001; Nilsson et al., 2012). One of the key benefits of this antibody is that it does not interact with host factors like the complement system, rheumatoid factor, and FC receptor. As a result, the immune system does not recognize it as a foreign object, and it does not cause any inflammatory complications (Schade et al., 2005).

Another advantage of this immunotherapy method is its low probability of causing allergies in people. This is due to the fact that eggs are a natural part of the human diet. Therefore, allergic reactions are limited since egg allergies are primarily related to the albumin found in egg whites (Rahman et al., 2013). This immunotherapy method did not cause any complications during the ten years of treatment for Pseudomonas aeruginosa infection (Nilsson et al., 2007a,b).

The evolutionary divergence between mammals and birds has also made them tend to bind to their target antigens even compared to mammalian IgG (Ikemori et al., 1993a,b; Ikemori et al., 1993a,b). IgY is found in high amounts in egg yolk. It is possible to isolate 60–150 mg of IgY per egg. Compared to serum antibodies from mammals such as mice or rabbits, IgY production is much more efficient. On average, each chicken can produce 22 g of IgY per year, of which only 10% is a specific antibody. In contrast, only 4 g of serum antibody can be isolated from rabbit blood. This method of producing IgY does not involve any stress or injury to the chickens, as the antibodies are separated from the eggs (Carlander et al., 1999a,b; Schade et al., 2005; Xu et al., 2011; Kovacs-Nolan and Mine, 2012; Li et al., 2015a,b). This treatment method has several advantages, such as being cost-effective, having a longer shelf life, and being non-invasive compared to other antibody-based treatments (Li et al., 2015a,b; Akbari et al., 2018).

Compared to other antibodies with low sialic acid, IgY has high amounts of sialic acid and lacks the hook region in its structure, which increases its half-life and stability (Liu, 2015; Gilgunn, et al., 2016). Some studies have indicated that IgY does not cause side effects and can be used safely for long-term use, especially in sensitive populations such as children, pregnant women, and the elderly (Xu et al., 2018). Oral antibodies like IgY are more effective than intravenous antibodies like IgG, especially against bacterial toxins in gastrointestinal infections (Roberts et al., 2012).

One of the benefits of this method is that it is highly effective. In laboratory conditions, it has been shown to completely inhibit the Helicobacter pylori bacteria when used at 16 mg/ml. However, the inhibitory effect is dependent on the concentration of antibodies. At low doses, this effect is not observed (Koo et al., 1999; Feng et al., 2013).

IgY has some advantages over antibiotics. Unlike other antibiotics, IgY does not accumulate in poultry and livestock meat, meaning there are no restrictions on consuming such meat. Additionally, due to its natural properties, IgY does not cause environmental pollution (Li et al., 2015). This antibody can help immunocompromised patients, such as those undergoing chemotherapy treatment. These patients have an incomplete immune system and produce insufficient amounts of antibodies. This humoral immune deficiency can be resolved by introducing antibodies (Müller et al., 2015).

IgY disadvantages

One issue with this technology is that the production of IgY antibodies can be slow, taking up to 4 weeks to produce in chickens even under optimal conditions. Furthermore, certain studies have suggested that the presence of human antibodies against IgY may decrease the efficacy of this treatment (Díaz et al., 2014). The level of specific IgY in chickens increases significantly 28 days after antigen injection, reaching its peak on day 35 (Najdi et al., 2016). However, producing engineered monoclonal antibodies from polyclonal fragments may overcome these problems (Yamanaka et al., 1996). It is challenging to use oral IgY in patients due to its breakdown by the digestive system. Although many studies have been conducted to improve the IgY drug delivery system, it is still sensitive to gastric acidity and protease enzymes. Despite being more stable than other antibodies because of the absence of a hinge structure, IgY remains susceptible to degradation (Zhang et al., 2016).

Several methods have been proposed to solve this problem, including using microbeads containing chicken antibodies and coating technologies such as alginate, calcium chitosan, and calcium pectinate (Sandolo et al., 2011; Wong et al., 2011; Yoshida et al., 2013; Bansal et al., 2014; Zhang et al., 2016). Carbonate buffer has been shown to protect IgY from degradation in the stomach of animal models (Roberts et al., 2012). Compounds like sorbitol, sucrose, and mannitol can stabilize this antibody against adverse temperature and acidity conditions (Müller et al., 2015). Research suggests that the unique hydrophobicity of IgY, when compared to IgG, could potentially enhance its stability. This intriguing characteristic of IgY, particularly when derived from egg yolk, may lead to improved patient outcomes compared to its purified form (Dávalos-Pantoja et al., 2000).

However, a significant challenge with IgY is that its antibodies lack inhibitory properties once the Shiga toxin binds to the target. This limitation in efficacy, confined to initial use, underscores the need for further research and development (Neri et al., 2011). Caution is warranted when considering high doses of IgY, as studies on pigs have shown that excessive administration may lead to allergic reactions such as serum sickness. Furthermore, it can also trigger systemic and local responses, highlighting the importance of careful dosage management (Torché et al., 2006; Vega et al., 2012). Passive immunity, a viable treatment option, is not without its risks. The antibodies it generates, crucial for its effectiveness, have a limited lifespan in the patient’s blood. This necessitates a continuous supply of these antibodies to maintain their levels, a challenge that underscores the complexity of this treatment option. Large-scale production of these antibodies is, therefore, a necessity, a process that carries its own set of challenges (Chalghoumi et al., 2009).

A study on the use of IgY in treating Acinetobacter baumannii pneumonia reported a surprising finding. Instead of leading to recovery, the treatment resulted in an increase in mortality and bacterial load in the mouse model. This unexpected outcome, known as antibody-dependent enhancement (ADE), raises significant concerns about the safety and efficacy of passive immunity. The researchers speculate that this may have been due to the shedding of the bacterial capsule (Jahangiri et al., 2021).

Fig. 1. Different hypotheses of IgY antibody response to bacterial infections designed by BioRender website (https://www.biorender.com/).

Table 1. Advantages and disadvantages of immunoglobulin Y (IgY).

In a clinical trial, all participants reported mild side effects except for one who experienced severe nausea and vomiting (Jonsson et al., 2015). More investigations on the appropriate dosage and administration route can minimize patient complications. Table 1 lists the advantages and disadvantages of using IgY antibody. According to the above studies, the problems of using this antibody can be solved by eliminating side effects such as ADE through appropriate doses and routes of administration and recombinant antigens. In addition, determining the appropriate release methods and taking frequent doses increased its stability and effectiveness in the body.


Conclusion

The excessive use of antibiotics and the emergence of antibiotic resistance have led to the development of new treatment technologies. One of these methods is the use of antibodies as passive immunity. Antibodies have a natural structure similar to human proteins, making them an effective tool in treating various microbial infections. Previous studies have shown that their side effects or minor disadvantages, such as ADE, can be eliminated with the help of bioinformatics methods and the production of recombinant antigens. However, more research is needed to determine their appropriate dose and route of administration for widespread use in various infections.


Acknowledgments

Not applicable.

Conflict of interest

The authors state no conflicts of interest that could have influenced this work.

Funding

None.

Authors’ contributions

Z.E and S.K prepared the initial manuscript. K.G, M.K, and Z.E were responsible for drafting and editing the final article. K.G was the supervisor too. All authors have read and approved the final manuscript.

Data availability

All data are provided in the manuscript.


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How to Cite this Article
Pubmed Style

Esmaeili Z, Shahsavar SK, Keikha M, Ghazvini K. Chicken immunoglobulin (IgY) as an alternative treatment for bacterial infections, emphasizing advantages, disadvantages and mechanisms. J Microbiol Infect Dis. 2024; 14(3): 95-102. doi:10.5455/JMID.2024.v14.i3.2


Web Style

Esmaeili Z, Shahsavar SK, Keikha M, Ghazvini K. Chicken immunoglobulin (IgY) as an alternative treatment for bacterial infections, emphasizing advantages, disadvantages and mechanisms. https://www.jmidonline.org/?mno=206671 [Access: November 24, 2024]. doi:10.5455/JMID.2024.v14.i3.2


AMA (American Medical Association) Style

Esmaeili Z, Shahsavar SK, Keikha M, Ghazvini K. Chicken immunoglobulin (IgY) as an alternative treatment for bacterial infections, emphasizing advantages, disadvantages and mechanisms. J Microbiol Infect Dis. 2024; 14(3): 95-102. doi:10.5455/JMID.2024.v14.i3.2



Vancouver/ICMJE Style

Esmaeili Z, Shahsavar SK, Keikha M, Ghazvini K. Chicken immunoglobulin (IgY) as an alternative treatment for bacterial infections, emphasizing advantages, disadvantages and mechanisms. J Microbiol Infect Dis. (2024), [cited November 24, 2024]; 14(3): 95-102. doi:10.5455/JMID.2024.v14.i3.2



Harvard Style

Esmaeili, Z., Shahsavar, . S. K., Keikha, . M. & Ghazvini, . K. (2024) Chicken immunoglobulin (IgY) as an alternative treatment for bacterial infections, emphasizing advantages, disadvantages and mechanisms. J Microbiol Infect Dis, 14 (3), 95-102. doi:10.5455/JMID.2024.v14.i3.2



Turabian Style

Esmaeili, Zahra, Sara Kamal Shahsavar, Masoud Keikha, and Kiarash Ghazvini. 2024. Chicken immunoglobulin (IgY) as an alternative treatment for bacterial infections, emphasizing advantages, disadvantages and mechanisms. Journal of Microbiology and Infectious Diseases, 14 (3), 95-102. doi:10.5455/JMID.2024.v14.i3.2



Chicago Style

Esmaeili, Zahra, Sara Kamal Shahsavar, Masoud Keikha, and Kiarash Ghazvini. "Chicken immunoglobulin (IgY) as an alternative treatment for bacterial infections, emphasizing advantages, disadvantages and mechanisms." Journal of Microbiology and Infectious Diseases 14 (2024), 95-102. doi:10.5455/JMID.2024.v14.i3.2



MLA (The Modern Language Association) Style

Esmaeili, Zahra, Sara Kamal Shahsavar, Masoud Keikha, and Kiarash Ghazvini. "Chicken immunoglobulin (IgY) as an alternative treatment for bacterial infections, emphasizing advantages, disadvantages and mechanisms." Journal of Microbiology and Infectious Diseases 14.3 (2024), 95-102. Print. doi:10.5455/JMID.2024.v14.i3.2



APA (American Psychological Association) Style

Esmaeili, Z., Shahsavar, . S. K., Keikha, . M. & Ghazvini, . K. (2024) Chicken immunoglobulin (IgY) as an alternative treatment for bacterial infections, emphasizing advantages, disadvantages and mechanisms. Journal of Microbiology and Infectious Diseases, 14 (3), 95-102. doi:10.5455/JMID.2024.v14.i3.2