IgY: a key isotype in antibody evolution

Immunoglobulin Y (IgY) is central to our understanding of immunoglobulin evolution. It has links to antibodies from the ancestral IgM to the mucosal IgX and IgA, as well as to mammalian serum IgG and IgE. IgY is found in amphibians, birds and reptiles, and as their most abundant serum antibody, is orthologous to mammalian IgG. However, IgY has the same domain architecture as IgM and IgE, lacking a hinge region and comprising four heavy‐chain constant domains. The relationship between IgY and the mucosal antibodies IgX and IgA is discussed herein, in particular the question of how IgA could have contributed to the emergence of IgY. Although IgY does not contain a hinge region, amphibian IgF and duck‐billed platypus IgY/O, which are closely related to IgY, do contain this region, as does mammalian IgG, IgA and IgD. A hinge region must therefore have evolved at least three times independently by convergent evolution. In the absence of three‐dimensional structural information for the complete Fc fragment of chicken IgY (IgY‐Fc), it remains to be discovered whether IgY displays the same conformational properties as IgM and IgE, which exhibit substantial flexibility in their Fc regions. IgY has three characterised Fc receptors, chicken Ig‐like receptor AB1 (CHIR‐AB1), the chicken yolk sac IgY receptor (FcRY) and Gallus gallus Fc receptor (ggFcR). These receptors bind to IgY at sites that are structurally homologous to mammalian counterparts; IgA/FcαRI for CHIR‐AB1, IgG/FcRn for FcRY and IgE/Fc?RI and IgG/FcγR for ggFcR. These resemblances reflect the close evolutionary relationships between IgY and IgA, IgG and IgE. However, the evolutionary distance between birds and mammals allows for the ready generation of IgY antibodies to conserved mammalian proteins for medical and biotechnological applications. Furthermore, the lack of reactivity of IgY with mammalian Fc receptors, and the fact that large quantities of IgY can be made quickly and cheaply in chicken eggs, offers important advantages and considerable potential for IgY in research, diagnostics and therapeutics.     

Stable production of recombinant chicken antibody in CHO-K1 cell line.

When compared with mammalian IgG, chicken IgY is advantageous in terms of cross-reactivity. In this study, two plasmids were constructed for expression of recombinant chicken IgY derived from a chicken hybridoma. The first was for expression of the light (L) chain, and the other was for the heavy (H) chain with a histidine (His) tag at the carboxy-terminal. After transfection of recombinant chicken IgY gene into Chinese hamster ovary cells, a transfectant designated HF33 that secreted the specific antibody was selected. HF33 cells produced recombinant IgY with His tag at 10-15 microg/10(6) cells/24 h. On Western blotting analysis, the recombinant IgY was detected as one band for the H chain and two bands for the L chain. The recombinant IgY was successfully purified in a one-step procedure using a nickel-affinity resin. These results indicate that the present recombinant chicken IgY is useful for further applications.     

Immunochemical characterization of an IgG-binding protein of Streptococcus suis

Several bacterial species express surface proteins with affinity for the constant region (F_c) of immunoglobulin (Ig) of different animal species. Previous studies from our group have reported the presence of an IgG-binding protein in various serotypes of Streptococcus suis . This molecule was also shown to bind in a non-immune fashion chicken IgY and to our knowledge this characteristic is unique. In the present study, by dot-blotting, we showed that the native protein, obtained by affinity chromatography, reacted more strongly with IgG from various animal species than the denatured material. Using a competitive enzyme-linked immunosorbent assay the affinity of the native 60-kDa protein (previously identified as a 52-kDa protein) towards IgG of various animal species was compared to pig IgG. Bovine, goat and human IgG were able to compete effectively with pig IgG whereas chicken IgY constituted a poor competitor. Peptide mapping analysis using denatured protein indicated that pig and bovine IgG recognized the same proteolytic fragment whereas chicken IgY did not. The smallest proteolytic fragment that retained the binding activity towards the IgG of the different animal species tested had a molecular mass of approximately 40 kDa. Fragments with M _r<40 kDa showed specific binding activities. That is, the smallest fragment binding pig and bovine IgG had a M _r of 30 kDa whereas for goat and human IgG a fragment of less than 16 kDa still showed binding activity. Finally, we observed that antisera raised against a heat-shock protein of Pseudomonas aeruginosa reacted with the 60-kDa S. suis protein indicating that the S. suis 60-kDa protein is a member of the 60-kDa hsp family that possesses the characteristic of binding in a non-immune way mammalian IgG and chicken IgY.     

Immunoglobulin genetics of Ornithorhynchus anatinus (platypus) and Tachyglossus aculeatus (short-beaked echidna)

In this paper, we review data on the monotreme immune system focusing on the characterisation of lymphoid tissue and of antibody responses, as well the recent cloning of immunoglobulin genes. It is now known that monotremes utilise immunoglobulin isotypes that are structurally identical to those found in marsupials and eutherians, but which differ to those found in birds and reptiles. Monotremes utilise IgM, IgG, IgA and IgE. They do not use IgY. Their IgG and IgA constant regions contain three domains plus a hinge region. Preliminary analysis of monotreme heavy chain variable region diversity suggests that the platypus primarily uses a single VH clan, while the short-beaked echidna utilises at least 4 distinct VH families which segregate into all three mammalian VH clans. Phylogenetic analysis of the immunoglobulin heavy chain constant region gene sequences provides strong support for the Theria hypothesis. The constant region of IgM has proven to be a useful marker for estimating the time of divergence of mammalian lineages.     

The interactions of calreticulin with immunoglobulin G and immunoglobulin Y

Calreticulin is a chaperone of the endoplasmic reticulum (ER) assisting proteins in achieving the correctly folded structure. Details of the binding specificity of calreticulin are still a matter of debate. Calreticulin has been described as an oligosaccharide-binding chaperone but data are also accumulating in support of calreticulin as a polypeptide binding chaperone. In contrast to mammalian immunoglobulin G (IgG), which has complex type N-glycans, chicken immunoglobulin Y (IgY) possesses a monoglucosylated high mannose N-linked glycan, which is a ligand for calreticulin. Here, we have used solid and solution-phase assays to analyze the in vitro binding of calreticulin, purified from human placenta, to human IgG and chicken IgY in order to compare the interactions. In addition, peptides from the respective immunoglobulins were included to further probe the binding specificity of calreticulin. The experiments demonstrate the ability of calreticulin to bind to denatured forms of both IgG and IgY regardless of the glycosylation state of the proteins. Furthermore, calreticulin exhibits binding to peptides (glycosylated and non-glycosylated) derived from trypsin digestion of both immunoglobulins. Additionally, calreticulin peptide binding was examined with synthetic peptides covering the IgG Cγ2 domain demonstrating interaction with approximately half the peptides. Our results show that the dominant binding activity of calreticulin in vitro is toward the polypeptide moieties of IgG and IgY even in the presence of the monoglucosylated high mannose N-linked oligosaccharide on IgY.     

Development of sandwich enzyme-linked immunosorbent assay for the detection of Cronobacter muytjensii (formerly called Enterobacter sakazakii)

This study aimed to produce a polyclonal antibody against Cronobacter muytjensii (C. muytjensii, formerly called Enterobacter sakazakii) and to develop an immunoassay for its detection. The optimum production of rabbit anti-C. muytjensii immunoglobulin G (IgG) and chicken anti-C. muytjensii IgY was reached in weeks 8 and 9, respectively. Purification of rabbit anti-C. muytjensii IgG from immunized rabbit sera was accomplished using the caprylic acid and ammonium sulfate precipitation method. As a result, sodium dodecyl sulfate-polyacrylamide gel electrophoresis produced two bands around 25 and 50 kDa, corresponding to a light and a heavy chain, respectively. The optimized conditions for sandwich enzyme-linked immunosorbent assay were using rabbit anti-C. muytjensii IgG (1 μg/mL) as a detection antibody and chicken anti-C. muytjensii IgY (10 μg/mL) as a capture antibody. In this assay, no cross-reactivity was observed with the other genera of pathogenic bacteria tested, which included Escherichia coli O157:H7, Salmonella typhimurium, Staphylococcus aureus, Bacillus cereus and Listeria monocytogenes. The developed assay did not show cross-reactivity with other tested species of Cronobacter and Enterobacter genera such as C. turicensis, C. sakazakii, E. aerogenes, E. pulveris and E. helveticus. The detection limit of sandwich ELISA for C. muytjensii was found to be 2.0 × 10(4) colony forming units (CFU)/mL. In addition, detection of C. muytjensii in infant formula powder showed a low matrix effect on the detection curve of sandwich ELISA for C. muytjensii, the detection limit being found to be 6.3 × 10(4) CFU/mL. These findings demonstrate that the developed method is able to detect all strains of C. muytjensii. Hence, this ELISA technique has potent application for the rapid and accurate detection of C. muytjensii in dietary foods.     

Site-specific N-glycosylation of chicken serum IgG

Avian serum immunoglobulin (IgG or IgY) is functionally equivalent to mammalian IgG but has one additional constant region domain (CH2) in its heavy (H) chain. In chicken IgG, each H-chain contains two potential N-glycosylation sites located on CH2 and CH3 domains. To clarify characteristics of N-glycosylation on avian IgG, we analyze N-glycans from chicken serum IgG by derivatization with 2-aminopyridine (PA) and identified by HPLC and MALDI-TOF-MS. There were two types of N-glycans: (1) high-mannose-type oligosaccharides (monoglucosylated 26.8%, others 10.5%) and (2) biantennary complex-type oligosaccharides (neutral, 29.9%; monosialyl, 29.3%; disialyl, 3.7%) on molar basis of total N-glycans. To investigate the site-specific localization of different N-glycans, chicken serum IgG was digested with papain and separated into Fab [containing variable regions (VH + VL) + CH1 + CL] and Fc (containing CH3 + CH4) fragments. Con A stained only Fc (CH3 + CH4) and RCA-I stained only Fab fractions, suggesting that high-mannose-type oligosaccharides were located on Fc (CH3 + CH4) fragments, and variable regions of Fab contains complex-type N-glycans. MS analysis of chicken IgG-glycopeptides revealed that chicken CH3 domain (structurally equivalent to mammalian CH2 domain) contained only high-mannose-type oligosaccharides, whereas chicken CH2 domain contained only complex-type N-glycans. The N-glycosylation pattern on avian IgG is more analogous to that in mammalian IgE than IgG, presumably reflecting the structural similarity to mammalian IgE.     

Characterization of the optimized C2 domain of protein G: finding its additional chicken IgY-binding ability

The C2 domain of streptococcal protein G is a small (55 residue) peptide with immunoglobulin-binding activity. Following codon optimization, the gene was divided into four oligonucleotide fragments and amplified by overlap PCR. The recombinant plasmid pET30a-C2 was transformed into Escherichia coli Rosetta (DE3) PLysS for expression. After purification by Ni–NTA, the fusion protein was identified by western-blotting, Dot-ELISA and ELISA. His-tagged C2 bound to human, rabbit, cattle, pig, goat, mouse or guinea pig IgG had no affinity for goose, duck, wild duck, wild turkey and red-crowned crane IgY. Its affinity for chicken IgY, however, was comparable to that of guinea pig IgG. The C2 domain may therefore provide an ideal material for the purification and detection of immunoglobulin G from various mammals.     

Molecular stability of chicken and rabbit immunoglobulin G.

Molecular stability of chicken egg yolk immunoglobulin G (IgY) and that of rabbit IgG were compared by measuring antibody activities and conformational changes. Stability of rabbit IgG to acid denaturation was much higher than that of IgY. Conformation of the IgY molecule was readily changed in acidic conditions, resulting in a rapid loss of antibody activity. Much less stable natures of IgY to heat-treatment and guanidine-HCl denaturation than rabbit IgG were also observed. Differences in the structure between the two immunoglobulins that might participate in their different stability were inferred from their amino acid sequence data. Importance of the intramolecular disulfide linkage in the rabbit light chain and some other structural differences were suggested.     

Genomic organization and sequences of immunoglobulin light chain genes in a primitive vertebrate suggest coevolution of immunoglobulin gene organization.

The genomic organization and sequence of immunoglobulin light chain genes in Heterodontus francisci (horned shark), a phylogenetically primitive vertebrate, have been characterized. Light chain variable (VL) and joining (JI) segments are separated by 380 nucleotides and together with the single constant region exon (CI), occupy less than 2.7 kb, the closest linkage described thus far for a rearranging gene system. The VL segment is flanked by a characteristic recombination signal sequence possessing a 12 nucleotide spacer; the recombination signal sequence flanking the JL segment is 23 nucleotides. The VL genes, unlike heavy chain genes, possess a typical upstream regulatory octamer as well as conserved enhancer core sequences in the intervening sequence separating JL and CL. Restriction mapping and genomic Southern blotting are consistent with the presence of multiple light chain gene clusters. There appear to be considerably fewer light than heavy chain genes. Heavy and light chain clusters show no evidence of genomic linkage using field inversion gel electrophoresis. The findings of major differences in the organization and functional rearrangement properties of immunoglobulin genes in species representing different levels of vertebrate evolution, but consistent similarity in the organization of heavy and light chain genes within a species, suggests that these systems may be coevolving.     

A Monomeric Chicken IgY Receptor Binds IgY with 2:1 Stoichiometry

IgY is the principal serum antibody in birds and reptiles, and an IgY-like molecule was the evolutionary precursor of both mammalian IgG and IgE. A receptor for IgY on chicken monocytes, chicken leukocyte receptor AB1 (CHIR-AB1), lies in the avian leukocyte receptor cluster rather than the classical Fc receptor cluster where the genes for mammalian IgE and IgG receptors are found. IgG and IgE receptors bind to the lower hinge region of their respective antibodies with 1:1 stoichiometry, whereas the myeloid receptor for IgA, FcαRI, and the IgG homeostasis receptor, FcRn, which are found in the mammalian leukocyte receptor cluster, bind with 2:1 stoichiometry between the heavy chain constant domains 2 and 3 of each heavy chain. In this paper, the extracellular domain of CHIR-AB1 was expressed in a soluble form and shown to be a monomer that binds to IgY-Fc with 2:1 stoichiometry. The two binding sites have similar affinities: K_a1 = 7.22 ± 0.22 × 10⁵ m⁻¹ and K_a2 = 3.63 ± 1.03 × 10⁶ m⁻¹ (comparable with the values reported for IgA binding to its receptor). The affinity constants for IgY and IgY-Fc binding to immobilized CHIR-AB1 are 9.07 ± 0.07 × 10⁷ and 6.11 ± 0.02 × 10⁸ m⁻¹, respectively, in agreement with values obtained for IgY binding to chicken monocyte cells and comparable with reported values for human IgA binding to neutrophils. Although the binding site for CHIR-AB1 on IgY is not known, the data reported here with a monomeric receptor binding to IgY at two sites with low affinity suggest an IgA-like interaction.Fc receptors link the specificity of the adaptive immune system with the effector mechanisms of innate immune cells. In birds and reptiles, IgY is the principal serum antibody, and both mammalian IgG and IgE have evolved from an IgY-like ancestor, so studies of IgY offer insights into their origins (1). The historical contribution of chicken immunology to a wider understanding of the subject has been considerable (2), and recently several chicken IgY-Fc receptors have been identified. In this paper, the chicken antibody, IgY, is shown to bind to a chicken leukocyte receptor, CHIR-AB1,⁴ in a different manner from that of its mammalian orthologues, IgG and IgE, to their respective Fc receptors.Phagocytosis, mediated in mammals by IgG, and passive cutaneous anaphylaxis, mediated by both IgG and IgE in mammals, have been observed in chickens (3, 4), presumably both effected by IgY. In vitro, IgY binds to monocyte cell lines (5, 6), and an IgY receptor (CHIR-AB1) has been identified that is able to mediate the influx of calcium into cells (5).The genes for the mammalian high affinity IgE receptor, and several IgG receptors, are located in the classical Fc receptor cluster, whereas in chickens, this cluster is represented by a single gene, the product of which has been expressed and found not to bind IgY (7). Intriguingly, the first IgY leukocyte receptor, CHIR-AB1, was found to be a member of the chicken leukocyte receptor cluster (LRC) (5), adjacent to over 100 genes with high intersequence homology (8). This finding, together with phylogenetic analysis of the orthologous Fc receptor gene clusters (7, 9), implies that during the evolution of the IgY-like ancestor of both IgG and IgE, antibody-Fc binding function migrated from proteins expressed in the LRC to those in the classical Fc receptor cluster. The human LRC is the site of FcαRI, the leukocyte receptor for IgA (an antibody involved in mucosal immunity), the fetal IgG receptor (FcRn, involved in adult IgG homeostasis), and also a number of natural killer cell receptors including the HLA-G ligand, KIR2DL4 (10). A further leukocyte receptor for chicken IgY, also related to LRC receptors, was identified recently, on chromosome 20 (11), and remains to be characterized.Typically, the stoichiometry of the receptor-antibody complex differs for receptors located in the classical Fc receptor cluster and the LRC. Crystal structures of IgG complexes with FcγRIII and of IgE with FcϵRI show 1:1 receptor:antibody stoichiometry, with the receptor binding across both heavy chains in the lower hinge (12). In contrast, the crystal structure of FcαRI complexed with IgA shows 2:1 stoichiometry (13) as does that of FcRn with IgG (14), with the two receptors binding between the heavy chain constant domains 2 and 3 on each heavy chain. The IgY/receptor interaction could have either stoichiometry; on the one hand, IgY is an orthologue of IgG and IgE, which can both show 1:1 stoichiometry, but on the other hand, the location of the IgY receptor, CHIR-AB1, in the same gene cluster as the IgA and FcRn receptors suggests the possibility of a 2:1 stoichiometry. Consistent with either of these binding modes, the crystal structure of IgY-Fc reveals that many of the residues located in the receptor-binding sites in human IgE, IgG, and IgA are present and accessible in IgY (15).The single extracellular domain of the chicken leukocyte IgY receptor, CHIR-AB1, has been expressed in insect cells by Arnon et al. (16), who showed that this preparation consists of a mixture of soluble monomer and dimer. Because of the heterogeneity of the protein, it was not possible to ascertain whether the observed 2:1 stoichiometry of receptor binding to antibody involved two monomers or a single dimer binding to IgY. Thus, it was not possible to answer the question of whether the antibody-receptor complex most resembles that of human IgA or of IgG and IgE. We have expressed the extracellular domain of CHIR-AB1 in human HEK cells. It is a monomer, and we report here that it binds to IgY and IgY-Fc with 2:1 stoichiometry.     

Identification of the serine residue phosphorylated by protein kinase C in vertebrate nonmuscle myosin heavy chains

Two-dimensional mapping of the tryptic phosphopeptides generated following in vitro protein kinase C phosphorylation of the myosin heavy chain isolated from human platelets and chicken intestinal epithelial cells shows a single radioactive peptide. These peptides were found to comigrate, suggesting that they were identical, and amino acid sequence analysis of the human platelet tryptic peptide yielded the sequence -Glu-Val-Ser-Ser(PO4)-Leu-Lys-. Inspection of the amino acid sequence for the chicken intestinal epithelial cell myosin heavy chain (196 kDa) derived from cDNA cloning showed that this peptide was identical with a tryptic peptide present near the carboxyl terminal of the predicted alpha-helix of the myosin rod. Although other vertebrate nonmuscle myosin heavy chains retain neighboring amino acid sequences as well as the serine residue phosphorylated by protein kinase C, this residue is notably absent in all vertebrate smooth muscle myosin heavy chains (both 204 and 200 kDa) sequenced to date.     

A third immunoglobulin class in amphibians

A new class of immunoglobulin (IgX) has been found in the South African frog, Xenopus laevis, and other related species. IgX can be immunoprecipitated by monoclonal antibodies directed against determinants found on Xenopus light chain, or on variable regions of heavy chains. Reagents specific for the heavy chain of IgM or the amphibian IgG equivalent, IgY, failed to react with IgX. IgX, which exists in serum as a polymer, is composed of subunits of disulfide-bonded heavy chains of 80,000 daltons and light chains of 25,000 to 29,000 daltons. Like mu, the heavy chain of IgX carries a large amount of asparagine-linked carbohydrate, but the partial peptide maps of the two are different. Although the concentration of IgX varies greatly in the serum of individual frogs, it is always secreted in cultures of cells from the spleen and intestinal mucosae.     

Reticuloendotheliosis Virus Nucleic Acid Sequences in Cellular DNA

Reticuloendotheliosis virus 60S RNA labeled with (125)I, or reticuloendotheliosis virus complementary DNA labeled with (3)H, were hybridized to DNAs from infected chicken and pheasant cells. Most of the sequences of the viral RNA were found in the infected cell DNAs. The reticuloendotheliosis viruses, therefore, replicate through a DNA intermediate. The same labeled nucleic acids were hybridized to DNA of uninfected chicken, pheasant, quail, turkey, and duck. About 10% of the sequences of reticuloendotheliosis virus RNA were present in the DNA of uninfected chicken, pheasant, quail, and turkey. None were detected in DNA of duck. The specificity of the hybridization was shown by competition between unlabeled and (125)I-labeled viral RNAs and by determination of melting temperatures. In contrast, (125)I-labeled RNA of Rous-associated virus-O, an avian leukosis-sarcoma virus, hybridized 55% to DNA of uninfected chicken, 20% to DNA of uninfected pheasant, 15% to DNA of uninfected quail, 10% to DNA of uninfected turkey, and less than 1% to DNA of uninfected duck.     

Species specificity in avian sperm:perivitelline interaction

The interaction of chicken spermatozoa with the inner perivitelline layer from different avian species in vitro during a 5 min co-incubation was measured as the number of points of hydrolysis produced per unit area of inner perivitelline layer. The average degree of interaction, as a proportion of that between chicken spermatozoa and their homologous inner perivitelline layer, was: equal to or greater than 100% within Galliformes (chicken, turkey, quail, pheasant, peafowl and guineafowl); 44% within Anseriformes (goose, duck); and less than 30% in Passeriformes (Zebra Finch) and Columbiformes (collared-dove). The homologue of the putative chicken sperm-binding proteins, chicken ZP1 and ZP3, were identified by Western blotting with anti-chicken ZP1/ZP3 antibody in the perivitelline layers of all species. The functional cross-reactivity between chicken spermatozoa and heterologous inner perivitelline layer appeared to be linked to known phylogenetic distance between the species, although it was not related to the relative affinity of the different ZP3 homologues for anti-chicken ZP3. This work demonstrates that sperm interaction with the egg investment does not represent such a stringent species-specific barrier in birds as it does in mammals and marine invertebrates. This may be a factor in the frequency of hybrid production in birds.     

以猪IgG重链恒定区为抗原载体的抗口蹄疫病毒DNA疫苗的研制

口蹄疫(Foot-and-Mouth Disease, FMD)是当今世界上最为严重的家畜传染病之一,主要危害猪、牛、羊等偶蹄动物.FMD的致病原为FMD病毒(FMDV),属小RNA病毒科口蹄疫病毒属,有A、O、C、SATⅠ、SATⅡ、SATⅢ及AsiaⅠ共7个血清型.FMDV结构较简单,完整的病毒颗粒由4种结构蛋白VP1、VP2、VP3及VP4各60个拷贝构成的衣壳包裹一条单股正链RNA组成,其中VP1是主要的抗原蛋白[1].     

Isolation of a 97-kb minimal essential MHC B locus from a new reverse-4D BAC library of the golden pheasant

The bacterial artificial chromosome (BAC) system is widely used in isolation of large genomic fragments of interest. Construction of a routine BAC library requires several months for picking clones and arraying BACs into superpools in order to employ 4D-PCR to screen positive BACs, which might be time-consuming and laborious. The major histocompatibility complex (MHC) is a cluster of genes involved in the vertebrate immune system, and the classical avian MHC-B locus is a minimal essential one, occupying a 100-kb genomic region. In this study, we constructed a more effective reverse-4D BAC library for the golden pheasant, which first creates sub-libraries and then only picks clones of positive sub-libraries, and identified several MHC clones within thirty days. The full sequencing of a 97-kb reverse-4D BAC demonstrated that the golden pheasant MHC-B locus contained 20 genes and showed good synteny with that of the chicken. The notable differences between these two species were the numbers of class II B loci and NK genes and the inversions of the TAPBP gene and the TAP1-TAP2 region. Furthermore, the inverse TAP2-TAP1 was unique in the golden pheasant in comparison with that of chicken, turkey, and quail. The newly defined genomic structure of the golden pheasant MHC will give an insight into the evolutionary history of the avian MHC.     

IgY‐binding peptide screened from a random peptide library as a ligand for IgY purification

Chicken egg yolk immunoglobulin (IgY) is a functional substitute for mammalian IgG for antigen detection. Traditional IgY purification methods involve multi‐step procedures resulting in low purity and recovery of IgY. In this study, we developed a simple IgY purification system using IgY‐specific peptides identified by T7 phage display technology. From disulfide‐constrained random peptide libraries constructed on a T7 phage, we identified three specific binding clones (Y4‐4, Y5‐14, and Y5‐55) through repeated biopanning. The synthetic peptides showed high binding specificity to IgY‐Fc and moderate affinity for IgY‐Fc (K_d: Y4‐4 = 7.3 ± 0.2 μM and Y5‐55 = 4.4 ± 0.1 μM) by surface plasmon resonance analysis. To evaluate the ability to purify IgY, we performed immunoprecipitation and affinity high‐performance liquid chromatography using IgY‐binding peptides; the result indicated that these peptides can be used as affinity ligands for IgY purification. We then used a peptide‐conjugated column to purify IgY from egg yolks pre‐treated using an optimized delipidation technique. Here, we report the construction of a cost‐effective, one‐step IgY purification system, with high purity and recovery. © 2017 The Authors. Journal of Peptide Science published by European Peptide Society and John Wiley & Sons Ltd.