Identification of the lacZ insertion site and beta-galactosidase expression in transgenic chickens

The quail:chick chimera system is a classical research model in developmental biology. An improvement over the quail:chick chimera system would be a line of transgenic chickens expressing a reporter gene. Transgenic chickens carrying lacZ and expressing bacterial beta-galactosidase have been generated, but complete characterization of the insertion event and characterization of beta-galactosidase expression have not previously been available. The genomic sequences flanking the retroviral insertion site have now been identified by using inverse polymerase chain reaction (PCR), homozygous individuals have been identified by using PCR-based genotyping, and beta-galactosidase expression has been evaluated by using Western analysis and histochemistry. Based upon the current draft of the chicken genome, the viral insertion carrying the lacZ gene has been located on chromosome 11 within the predicted gene for neurotactin/fractalkine (CX3CL1); neurotactin mRNA expression appears to be missing from the brain of homozygous individuals. When Generation 2 (G2) lacZ-positive individuals were inter-mated, they generated 361 G3 progeny; 82 were homozyous for lacZ (22.7%), 97 were wild-type non-transgenic (26.9%), and 182 (50.4%) were hemizygous for lacZ. Western analysis revealed the highest expression in the muscle and liver. With the identification of homozygous birds, the line of chickens is now designated NCSU-Blue1.     

Microorganisms Responsible for Controlling the Populations of Escherichia coli and Enterococcus and the Consistency of Cecal Contents in the Chicken

A study was made to clarify what kinds of intestinal organisms might be responsible for controlling the populations of Escherichia coli and Streptococcus faecalis var. liquefaciens in the cecum and the consistency of the cecal contents of chickens. Germ-free chickens were inoculated orally with various mixtures of bacterial cultures alone or in combination, different dilutions of the cecal contents of chickens, different dilutions of the cecal contents treated by heating or with chloroform, the supernatant of diluted cecal contents, and dilutions of human feces. Factors controlling the E. coli population, enterococcal population, and consistency of the cecal contents were shown to be independent of one another. The ecosystem controlling the E. coli or enterococcal population was more complex than that controlling the consistency of the cecal contents. The former was composed of anaerobic and facultatively anaerobic bacteria isolated and heat- or chloroform-resistant organisms, and the latter of heat- or chloroform-resistant organisms alone, which were inferred not to be prevailing in the cecal contents of chickens. Discussion is made on ecological systems controlling the intestinal flora.     

Genetic and immunological characterization of naturally occurring recombinant B3 rats

The B-stock population of rats was bred for homozygosity at the loci controlling coat color. In this process, theAg-B1 andAg-B3 haplotypes became fixed in Hardy-Weinberg equilibrium. Extensive immunization and absorption studies showed that the specificities in the B-stock rats homozygous for theAg-B1 haplotype were the same as those found in the inbred F344 strain (Ag-B1), and that the specificities in the rats homozygous for theAg-B3 haplotype were the same as those found in the inbred BN (Ag-B3) strain. A homozygous line derived from the rats carrying theAg-B3 haplotype (B3) has the mixed lymphocyte reactivity and antibody responsiveness to poly (Glu⁵²Lys³³Tyr¹⁵) characteristic of the inbred strains in theAg-B4 group. Thus, it represents a naturally occurring recombination between the loci controlling MLR and immune responsiveness, on the one hand, and those controlling the Ag-B antigens on the other. Antibody responsiveness segregated with theAg-B3 haplotype in crosses between the B3 homozygotes and the low responder BUF and M520 strains; hence, this recombination is a stable one. There was no linkage of antibody formation or haplotype to coat color. The finding of a strain with a naturally occurring recombination in the major histocompatibility complex between the loci controlling mixed lymphocyte reactivity and the Ag-B histocompatibility antigens provides evidence for the separateness of these loci. Since the portion of the genetically determined mechanism controlling antibody responsiveness which is linked to the MHC was that characteristic of the MLR type, it too must lie outside the region defined by the serological specificities of theAg-B haplotype.     

Associations of A-FABP and H-FABP Markers with the Content of Intramuscular Fat in Beijing-You Chicken

This study has assessed the association of single nucleotide polymorphisms (SNP) identified in the adipocyte fatty acid binding protein (A-FABP) and heart-type fatty acid binding protein (H-FABP) genes with the content of intramuscular fat (IMF) in a population of male Beijing-You chickens. A previously described SNP in the chicken A-FABP gene had a significant (P < 0.05) effect on IMF content. Chickens inheriting the homozygous BB genotype at A-FABP had a significantly higher content of IMF in thigh muscles and breast muscles than did those inheriting the AA and AB genotypes. A novel SNP, identified here, in the H-FABP gene was also significantly (P < 0.05) associated with IMF content in thigh and breast muscle. Chickens inheriting the genotypes of DD and CD had much higher content of IMF than those inheriting the homozygous genotype of CC. Markers at the A-FABP and H-FABP genes were associated with IMF content in the studied population. Chickens inheriting the BB genotype at A-FABP, along with the CD genotype at H-FABP, produced muscles with a much higher content of IMF when compared with all other genotypes. A weak interaction between A-FABP and H-FABP was detected (P < 0.09) for IMF content in the tested population. The statistical significance of interaction is tentative because of the limited number of observations for some genotypic combinations. Markers identified within the A-FABP and H-FABP genes are suitable for future use in identifying chickens with the genetic potential to produce more desirable muscle with higher IMF content, at least in the population of Beijing-You male chickens.     

A polymorphic system related to but genetically independent of the chicken major histocompatibility complex

Analyses of the major histocompatibility complex (Mhc) in chickens have shown inconsistencies between serologically defined haplotypes and haplotypes defined by the restriction fragment patterns of Mhc class I and class II genes in Southern hybridizations. Often more than one pattern of restriction fragments for Mhc class I and/or class II genes has been found among DNA samples collected from birds homozygous for a single serologically defined B haplotype. Such findings have been interpreted as evidence for variability within the Mhc haplotypes of chickens not detected previously with serological methods. In this study of a fully pedigreed family over three generations, the heterogeneity observed in restriction fragment patterns was found to be the result of the presence of a second, independently segregating polymorphic Mhc-like locus, designated Rfp-Y. Three alleles (haplotypes) are identified in this new system.     

Tests of association of immunoglobulin allotype genes and viral oncogenesis in chickens

Chickens from Regional Poultry Research Laboratory (RPRL) inbred line 6₃ are resistant to virally-induced Marek's disease (MD) and lymphoid leukosis (LL) and are relatively strong regressors of virally-induced Rous sarcomas. In contrast, RPRL line 100 chickens are highly susceptible to MD and LL and are weaker regressors of Rous sarcomas than line 6₃. RPRL lines 100 and 6₃ differ for alleles at the IgG-1 (G-1) allotype locus, but have identical IgM-1 (M-1) allotype alleles. To test the possible association of the G-1 locus with variations in resistance to virally-induced tumors, homozygous and heterozygous genotypes among F₃ crosses were infected. F₃ chickens with different G-1 types were comparable in their resistance to MD tumors following inoculation with the JM strain of the MD virus, and for their ability to regress Rous sarcoma tumors induced by the Rous sarcoma virus (RSV) RAV-1. However, following RAV-1 virus infection a smaller proportion of G-1 ^a /G-1 ^a F₃ or F₄ birds developed LL tumors than G-1 ^a /G-1 ^e and G-1 ^e /G-1 ^e birds. Genes determining immunoglobulin heavy chains were therefore associated with a recessive resistance to B-cell lymphomagenesis in chickens.Deceased     

Primordial germ cell‐specific expression of eGFP in transgenic chickens

PR domain zinc finger protein 14 (PRDM14) plays an essential role in the development of primordial germ cells (PGCs) in mice. However, its functions in avian species remain unclear. In the present study, we used CRISPR/Cas9 to edit the PRDM14 locus in chickens in order to demonstrate its importance in development. The eGFP gene was introduced into the PRDM14 locus of cultured chicken PGCs to knockout PRDM14 and label PGCs. Chimeric chickens were established by a direct injection of eGFP knocked‐in (gene‐trapped) PGCs into the blood vessels of Hamburger–Hamilton stages (HH‐stages) 13–16 chicken embryos. Gene‐trapped chickens were established by crossing a chimeric chicken with a wild‐type hen with very high efficiency. Heterozygous gene‐trapped chickens grew normally and SSEA‐1‐positive cells expressed eGFP during HH‐stages 13–30. These results indicated the specific expression of eGFP within circulating PGCs and gonadal PGCs. At the blastodermal stage, the ratio of homozygous gene‐trapped embryos obtained by crossing heterozygous gene‐trapped roosters and hens was almost normal; however, all embryos died soon afterward, suggesting the important roles of PRDM14 in chicken early development.     

A genetic polymorphism of the complement component factor B in chickens not linked to the Major Histocompatibility Complex (MHC)

The complement component factor B in chickens exhibits a genetic polymorphism with three common phenotypes, F, F/S, and S. These phenotypes segregate in flocks of chickens homozygous for the MHC (B complex) of the chicken. Furthermore, a genetic analysis has shown that the described factor B polymorphism is not linked to the B complex. It is not known whether the molecular basis for this polymorphism is due to the existence of allelic forms of the structural gene or to some posttranslational modifications, but the finding is discussed in view of the, close linkage of factor B polymorphism with the MHC of all mammalian species investigated so far.     

Genetic control of chicken heterophil function in advanced intercross lines: associations with novel and with known <Emphasis Type="Italic">Salmonella</Emphasis> resistance loci and a likely mechanism for cell death in extracellular trap production

Heterophils, the avian polymorphonuclear leukocyte and the counterpart of mammalian neutrophils, generate the primary innate response to pathogens in chickens. Heterophil performance against pathogens is associated with host disease resistance, and heterophil gene expression and function are under genetic control. To characterize the genomic basis of heterophil function, heterophils from F₁₃ advanced intercross chicken lines (broiler × Leghorn and broiler × Fayoumi) were assayed for phagocytosis and killing of Salmonella enteritidis, oxidative burst, and extracellular trap production. A whole-genome association analysis of single nucleotide polymorphisms at 57,636 loci identified genomic locations controlling these functional phenotypes. Genomic analysis revealed a significant association of extracellular trap production with the SAL1 locus and the SLC11A1 gene, which have both been previously associated with resistance to S. enteritidis. Fine mapping supports SIVA1 as a candidate gene controlling SAL1-mediated resistance and indicates that the proposed cell-death mechanism associated with extracellular trap production, ETosis, likely functions through the CD27/Siva-1-mediated apoptotic pathway. The SLC11A1 gene was also associated with phagocytosis of S. enteritidis, suggesting that the Slc11a1 protein may play an additional role in immune response beyond depleting metal ions to inhibit intracellular bacterial growth. A region of chromosome 6 with no characterized genes was also associated with extracellular trap production. Further characterization of these novel genes in chickens and other species is needed to understand their role in polymorphonuclear leukocyte function and host resistance to disease.     

Effects of chicken intestinal antimicrobial peptides on humoral immunity of chickens and antibody titres after vaccination with infectious bursal disease virus vaccine in chicken

Abstract

Sixty chickens were randomly divided into two groups (30 chickens in each group) to determine the effect of oral administration of chicken intestinal antimicrobial peptides (CIAMP) on the humoral immune response. Chickens of both groups were fed the same diet. In the treatment group chickens received drinking water supplemented with CIAMP (1 µg/ml) right after hatching. Samples of blood, bursa of Fabricus, spleen and intestine were taken at day 1, 4, 7, 10 and 17 of experiment. CIAMP supplementation enhanced the content of IgG and IgM in serum from day 4 – 10 and day 10 – 17, respectively, (p < 0.05), IgM-forming cells in bursa of Fabricus and spleen at the age of 7 days (p < 0.05) and IgG-forming cells in bursa of Fabricus at the age of 4 days (p < 0.05). In addition, CIAMP enhanced the IgA-forming cells in caecal tonsils diffuse area at day 4 (p < 0.05). Furthermore, CIAMP enhanced the antibody response to infectious bursal disease virus vaccine (IBDV) in chickens 21 days following IBDV vaccine administration (p < 0.05). These results suggested that CIAMP could modulate the humoral immune response of chickens and increased the antibody titres of infectious bursal disease virus vaccine.     

Involvement of both HLA and Ig heavy chain haplotypes in human IgA deficiency

Immunoglobulin-A deficiency (IgA-D) is the most common human Ig class deficiency with an estimated frequency of approximately 1 in 500 in the Swedish population. We investigated the immunoglobulin heavy chain constant region gene segments (IGHC) in 103 individuals with IgA-D and the immunoglobulin heavy chain variable region gene segments (IGHV) in 20 of these, in order to identify a possible molecular basis of the defect. No deletions of IGHV gene segments of the VH2, VH5, and VH6 families or the IGHG genes were observed. In the IGHC, there were, however, differences in the restriction fragment length polymorphism frequencies of IGHG genes where the Bam HI haplotype H2 [IGHGP, 10 kilobases (kb), IGHG2, 25 kb; and IGHG4, 9.0 kb] was overrepresented. The mean serum levels of IgG4 and IgE were significantly lower in individuals (both IgA-D subjects and healthy controls) homozygous for the H2 haplotype than in individuals homozygous for the H1 haplotype (IGHGP, 8.8 kb, IGHG2, 13.5 kb, and IGHG4, 9.4 kb). IgA-D subjects homozygous for HLADQB1*0201 (DQw2), a marker that has previously been reported to show a strong association with IgA deficiency, showed a similar reduction of serum levels of IgG4 and IgE as compared with DQB1*0201 negative IgA-D subjects. These findings suggest that the two loci found to be associated with IgA deficiency may act via a common pathway. Address correspondence and offprint requests to: P. G. Olsson     

Serum IgG levels in the Storrs strain of hereditary muscular dystrophic chickens

IgG levels in sera of Storrs hereditary muscular dystrophic chickens were investigated. IgG levels in age-matched Storrs muscular dystrophic chickens varied, depending on the geographical location where the chickens were reared. IgG levels from muscular dystrophic chickens at varying ages of development were approximately 30% less than age-matched control values. Genetic analyses of F₁ hybrid, F₂ progeny, and testcross progeny showed the reduced IgG levels in the Storrs strain of muscular dystrophic chickens not to be correlated with the autosomal recessive muscular dystrophic trait, the degree of muscle destruction, nor with an autosomal recessive T cell defect. The studies reported here suggest (1) that the reduced IgG levels in the Storrs strain of muscular dystrophic chickens are due to strain differences and (2) that the mode of inheritance of serum IgG levels in the Storrs strain of muscular dystrophic chickens is polygenic.     

Genetic linkage between immune response to GAT and the fate of RSV-induced tumors in chickens

Recent studies suggest that the gene locus controlling the fate of tumors induced by Rous sarcoma virus (RSV) is linked to theB histocompatibility complex. Birds carrying the dominant allele regress the tumor; homozygous recessives being unable to do so, develop large tumors and die. These are called progressors.The Bryan strain of RSV was inoculated into 220 6 week old Leghorns homozygous forB ¹ B ¹,B ² B ², orB ¹⁹ B ¹⁹ of which the percentages of progressors were 79, 22 and 56, respectively. The balance of each were regressors and survived.TheB ¹ B ¹ test birds were derived from special matings, i.e., high and low immune responders to the amino acid polymer, GAT. Of 67 tests progeny of theB ¹ B ¹ GAT-low mating, 63 or 94% proved to be progressors, and 6% were regressors. Of 84 test progeny of theB ¹ B ¹ GAT-high matings, 67% were progressors, and 33% were regressors. The difference between the high and low GAT responders is highly significant and indicates that the locus controlling the fate of RSV-induced tumors is closely linked to the locus controlling immune response to GAT. The latter maps within theIr region of theB histocompatibility complex.     

Genetic resistance to fowl cholera is linked to the major histocompatibility complex

Chickens of the Iowa State S1 line have been selected for ability to regress Rous sarcoma virus-induced (RSV) tumors, humoral immune response to GAT (Ir-GAT), and erythrocyte antigen B. Sublines homozygous at the major histocompatibility complex (MHC), as well as F₁ heterozygotes and F₂ segregants, were tested for resistance to fowl cholera by challenge with Pasteurella multocida strain X73. Control of the response at high doses was associated in a preliminary study with Ir-GAT and response to RSV tumors. Genetic control of resistance to low doses of P. multocida was demonstrated via sublines and F₂ segregants to be linked with genes of the B-G region. Thus, genetic control of resistance to fowl cholera in chickens after exposure to Pasteurella multocida was shown to be linked to the major histocompatibility B complex, in this first demonstration of MHC-linked resistance to bacterial disease challenge.     

Immunogenetic and ontogenetic studies of chickens with selective IgA deficiency and autoimmune thyroiditis

In addition to spontaneous hypothyroidism and autoimmune thyroiditis, chickens of the obese strain (OS) have a high incidence of selective IgA deficiency. Elevated levels of serum IgM also occur in many OS chickens. The IgA deficiency begins by 2 weeks, the age when hypothyroidism is developing. Like thyroiditis, a greater incidence of IgA deficiency was noted in OS birds homozygous for the B¹ allele than for the B⁴ allele of the major histocompatibility locus. Although IgA deficiency occurs in both sexes, it is found in a higher frequency in females than males (2:1). An abnormal ontogenesis of immunological competence may influence both traits.     

Cre-loxP-mediated gene replacement: a mouse strain producing humanized antibodies

Background: The bacteriophage-derived Cre–loxP recombination system operates efficiently in mammalian cells. This system is particularly useful in gene-targeting experiments in the mouse, and has already been used to generate ‘clean’ deletions of target genes in the germ line, as well as to inactivate target genes in a conditional manner (based on regulated expression of the Cre recombinase). In principle, Cre–loxP-mediated recombination should also allow gene replacement, and thus the introduction of virtually any kind of mutation into the genome.Results We used the Cre–loxP system, in mouse embryonic stem cells, to replace the mouse gene Cγ 1, which encodes the constant region of the heavy chain of IgG1 antibodies, with its human counterpart. The mutation was transmitted through the mouse germ line, and the resulting mutant mice were crossed with mice expressing κ light chains with a human, instead of a mouse, constant region. Mice homozygous for both mutations produce humanized, κ-chain-bearing IgG1 antibodies at the same level and efficiency as wild-type mice produce murine IgG1 antibodies. These animals should enable the ex vivo production of humanized, chimeric monoclonal antibodies specific for any antigen to which the mouse can respond.Conclusion Cre–loxP-mediated gene replacement is a simple and efficient general method of targeted mutagenesis in the mouse.     

Serum and Egg Antibody Responses in Chickens to Escherichia coli

The effects of Freund’s adjuvants on antibody production in chickens against E. coli whole cells were examined. The levels of anti-E. coli IgG antibodies in serum were higher when Freund’s complete (FCA) or incomplete adjuvant (FIA) was administered than that without adjuvant. Production of antibodies recognizing E. coli cells and their lipopolysaccharide was enhanced by FIA, while both FIA and FCA enhanced production of antibodies recognizing outer membrane components. In contrast, serum IgM antibody levels were higher when no adjuvant was used. Anti-E. coli IgG antibodies in serum were efficiently transferred to egg yolk, giving antibody activity in egg yolk similar to that in serum. However, anti-E. coli IgM antibodies were not detected in the egg, suggesting that egg (white) IgM was not influenced by antigenic stimulation of the humoral immune system. Antimicrobial activity of the egg yolk IgG was highest when the bacteria antigen was injected with FIA.     

Recombination between genes coding for immune response and the serologically determined antigens in the chickenB system

Evidence is presented for a crossover between the genes coding for the serologically determined (SD) antigens on erythrocytes and an immune response gene (Ir-GAT) controlling immune response to the synthetic polypeptide GAT within theB complex, the MHC of chickens. TheIr-GAT ¹ andIr-GAT ¹⁹ alleles control low and high immune response to GAT, respectively. Both low and high responders were recovered as recombinants fromB ¹ B ¹ andB ¹⁹ B ¹⁹ birds. The low-responder haplotypes are homozygous for theIr-GAT ¹ allele and the high-responder haplotypes carry theIr-GAT ¹⁹ allele. Mortality forB ¹ B ¹ nonresponder birds was 39%, compared with 19% for theB ¹ B ¹ high responders; this suggests the possibility that genes located within the immune response region of theB complex exert some genetic control over viability and survival.The following abbreviations are used in this paper MHC major histocompatibility complex - Ir immune response - SD serologically determined - GA (L-glutamic acid⁶⁰, L-alanine⁴⁰) n - DNP-GL dinitrophenyl-(L-glutamic acid⁶⁰, L-lysine⁴⁰) - PLL poly-L-lysine - (T,G)-A--L poly-(L-tyrosine-L-glutamic acid)-poly-D, L-alanine-poly-L-lysine - GAT, GAT¹⁰ (L-glutamic acid⁶⁰ L-alanine³⁰ L-tyrosine¹⁰) n - CFA complete Freund's adjuvant - PBS phosphate-buffered saline