Immunoglobulin Y

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Immunoglobulin Y (abbreviated as IgY) is a type of immunoglobulin which is the major antibody in bird, reptile, and lungfish blood. It is also found in high concentrations in chicken egg yolk. As with the other immunoglobulins, IgY is a class of proteins which are formed by the immune system in reaction to certain foreign substances, and specifically recognize them.

Contents

IgY is often mislabelled as Immunoglobulin G (IgG) in older literature, and sometimes even in commercial product catalogues, due to its functional similarity to mammalian IgG and Immunoglobulin E (IgE). However, this older nomenclature is obsolete, since IgY differs both structurally and functionally from mammalian IgG, [1] and does not cross-react with antibodies raised against mammalian IgG. [2]

Since chickens can lay eggs almost every day, and the yolk of an immunised hen's egg contains a high concentration of IgY, chickens are gradually becoming popular as a source of customised antibodies for research. (Usually, mammals such as rabbits or goats are injected with the antigen of interest by the researcher or a contract laboratory.) [3]

Ducks produce a truncated form of IgY which is missing part of the Fc region. As a result, it cannot bind complement or be picked up by macrophages. [4] [5]

IgY has also been analyzed in the Chinese soft-shelled turtle, Pelodiscus sinensis . [6]

Characteristics

In chickens, immunoglobulin Y is the functional equivalent to Immunoglobulin G (IgG). Like IgG, it is composed of two light and two heavy chains. Structurally, these two types of immunoglobulin differ primarily in the heavy chains, which in IgY have a molecular mass of about 65,100 atomic mass units (amu), and are thus larger than in IgG. The light chains in IgY, with a molar mass of about 18,700 amu, are somewhat smaller than the light chains in IgG. The molar mass of IgY thus amounts to about 167,000 amu. The steric flexibility of the IgY molecule is less than that of IgG.

Functionally, IgY is partially comparable to Immunoglobulin E (IgE), as well as to IgG. However, in contrast to IgG, IgY does not bind to Protein A, to Protein G, or to cellular Fc receptors. Furthermore, IgY does not activate the complement system. The name Immunoglobulin Y was suggested in 1969 by G.A. Leslie and L.W. Clem, after they were able to show differences between the immunoglobulins found in chicken eggs, and immunoglobulin G. Other synonymous names are Chicken IgG, Egg Yolk IgG, and 7S-IgG.

Bioanalytic applications

As compared to mammalian antibodies, IgY offers various advantages for the targeted extraction of antibodies and their application in bioanalysis. Since the antibodies are extracted from the yolks of laid eggs, the method of antibody production is non-invasive. Thus, no blood must be taken from the animals for the extraction of blood serum.

The available quantity of a given antibody is considerably increased through repeated egg laying from the same hen. The cross-reactivity of IgY with proteins from mammals is also markedly less than that of IgG. Furthermore, the immune response against certain antigens in chickens is more strongly expressed than in rabbits or other mammals.

Of the immunoglobulins arising during the immune response, only IgY is found in chicken eggs. Thus, in preparations from chicken eggs, there is no contamination with Immunoglobulin A (IgA) or Immunoglobulin M (IgM). The yield of IgY from a chicken egg is comparable to that of IgG from rabbit serum.

One disadvantage of IgY, as compared to mammalian antibodies, is that the isolation of IgY from egg yolk is more difficult than the isolation of IgG from blood serum. This is due in large part to the fact that IgY cannot be bound with Protein A and Protein G. Thus, it cannot be separated from other components of the assay, for example from other proteins. Additionally, the egg yolk's rich store of lipids and lipoproteins must be removed. [7] Antibody-containing blood serums, on the other hand, can sometimes be directly used in bioanalysis, i.e., without complicated isolation steps.

Utilization in foods

Particularly in Asian countries, IgY has been clinically tested as a food supplement and preservative. For example, yogurt products containing pathogen specific IgY, have been tested for their ability to reduce Helicobacter pylori in the stomach by hindering the attachment of the bacterium to the stomach lining. [8] [9] The IgY used for this purpose is extracted from the eggs of immunized hens. Antibodies against Salmonella and other bacteria, as well as against viruses, are produced in this manner, and employed as a nutritional component for protection against these pathogens. The Food Safety Lab of Ocean University of China has experimented with using IgY specific to the bacteria Shewanella putrefaciens and Pseudomonas fluorescens as a food preservative for fish. The shelf life of fish treated with the IgY was extended from 9 days to 12 – 15 days demonstrating a significant antimicrobial activity to the specific bacteria. [10]

Anti-Fel d1 egg IgY immunoglobulin has been successfully tested to reduce active Fel d1 in cats saliva in order to lower allergenic potential of treated cats. [11]

Literature

Related Research Articles

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References

  1. Larsson A, Bålöw RM, Lindahl TL, Forsberg PO. Poult Sci. 1993 Oct;72(10):1807-12.Chicken antibodies: taking advantage of evolution--a review.
  2. Structure, Function and Physicochemical Properties of IgY Archived 2014-05-21 at the Wayback Machine , Gallus Immunotech. Accessed 28 October 2010.
  3. REVIEW - Chicken Antibodies- IgY - http://www.oramune.com/custom.aspx?id=7 Archived 2009-06-03 at the Wayback Machine
  4. Davison, T. Fred; Bernd Kaspers; Karel Antoni Schat (2008). Avian Immunology. Academic Press. p. 418. ISBN   978-0-12-370634-8.
  5. Lundqvist, Mats L.; Darlene L. Middleton; Cynthia Radford; Gregory W. Warr; Katharine E. Magor (2006). "Immunoglobulins of the non-galliform birds: Antibody expression and repertoire in the duck". Developmental & Comparative Immunology. 30 (1–2): 93–100. doi:10.1016/j.dci.2005.06.019. PMC   1317265 . PMID   16150486.
  6. Zhen Xu, Gai L Wang, P Nie. Mol Immunol. 2009 vol. 46 (10) pp. 2124-32. IgM, IgD and IgY and their expression pattern in the Chinese soft-shelled turtle Pelodiscus sinensis.
  7. Elvira Schecklies (1996), Polyklonale Antikörper (in German) (Erste Auflage ed.), Weinheim: VCH Verlagsgesellschaft mBH, ISBN   3-527-30078-3
  8. Suzuki H, Nomura S, Masaoka T, et al. (July 2004). "Effect of dietary anti-Helicobacter pylori-urease immunoglobulin Y on Helicobacter pylori infection". Aliment. Pharmacol. Ther. 20 Suppl 1: 185–92. doi: 10.1111/j.1365-2036.2004.02027.x . PMID   15298626. S2CID   19455348.
  9. Horie K, Horie N, Abdou AM, et al. (December 2004). "Suppressive effect of functional drinking yogurt containing specific egg yolk immunoglobulin on Helicobacter pylori in humans". Journal of Dairy Science . 87 (12): 4073–9. doi: 10.3168/jds.S0022-0302(04)73549-3 . PMID   15545368.
  10. Xu, Yafu; Lin, Hong; Sui, Jianxin; Cao, Limin (November 2011). "Effects of specific egg yolk antibody (IgY) on the quality and shelf life of refrigerated paralichthys olivaceus". Journal of the Science of Food and Agriculture. 92 (6): 1267–72. doi:10.1002/jsfa.4693. PMID   22052727 . Retrieved 19 February 2015.
  11. Ebenezer, Satyaraj; Cari, Gardner; Ivan, Filipi; Kerry, Cramer; Scott, Sherrill (2019). "Reduction of active Fel d1 from cats using an antiFel d1 egg IgY antibody". Immunity, Inflammation and Disease. 7 (2): 68–73. doi:10.1002/iid3.244. PMC   6485700 . PMID   30851084.
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