The phylogenetic relationships of immunoglobulin allotypes and 7S immunoglobulin isotypes of chickens and other phasianoids (turkey,pheasant, quail)

Pheasants, quail and turkeys from different geographical locations were surveyed for the presence of eight 7S Ig and four IgM chicken allotypes. No IgM and only two 7S Ig allotypes were detected. Chicken 7S Ig allotypic specificity G-1.7 cross-reacted with pheasant and turkey isotypic specificities, and was absent in quail. The other determinant (G-1.9) cross-reacted with an allotype found only in turkeys and golden pheasants. These data suggest that G-1.7 and G-1.9 are probably phylogenetically ancient determinants and that polymorphism of chicken immunoglobulins arose after divergence of chickens from other phasianoid birds. Based on the allotypic and isotypic analysis of the 7S Ig antigenic determinants, turkey 7S Ig was as closely related to chicken 7S Ig as was pheasant 7S Ig. Jungle fowl, the ancestor of chickens, had most of the chicken 7S Ig and IgM allotypes present as polymorphic markers.     

Genetic nomenclature for chicken immunoglobulin allotypes: An extensive survey of inbred lines and antisera

Based on a survey of 36 inbred and 8 partially inbred chicken lines and outbred jungle fowl, and with 29 alloantisera generated in different laboratories, 13 7S Ig and 5 IgM allotypes were designated and a new system of nomenclature for chicken Ig polymorphisms was developed. The survey also revealed considerable genetic polymorphism in the structural gene(s) (G-1) responsible for the production of 7S Ig H chains. IgM H chains, encoded by theM-1 locus were less polymorphic. NineG-1 and fourM-1 gene alleles were delineated in highly inbred lines by the formation of unique combinations ofG-1 orM-1 specificities. Five additionalG-1 alleles were found in chicken lines and jungle fowl segregating for allotypes. Thirty-three percent of theG-1M-1 haplotypes theoretically expected, were detected in inbred lines.     

Structural and genetic studies on chicken 7S immunoglobulin allotypes. IV. The presence of an unexpected chicken immunoglobulin heavy chain allotype: subclass or pseudoallele?

Low concentrations of allotypic specificity CS-1.1 were detected in the sera of two inbred chicken lines [University of California, Davis (UCD) 7 and Regional Poultry Research Laboratory 15I4] previously reported to lack this specificity. The CS-1.1 alloantigen in 15I4 chickens has the same specificity as the major allotype in a line of chickens (UCD 2) in which it was initially defined. In 15I4 chickens, CS-1.1 allotype is present on a population of molecules distinct from those which carry the major allotype; thus a second 7S Ig H chain locus, CS-2, is proposed. The concentration of CS-1.1-bearing molecules determined by two different methods was 7 microgram/ml and 230 microgram/ml in 15I4, whereas UCD 2 chickens had 4 mg/ml of CS-1.1 molecules. The levels of CS-1.1 inhibitory activity in 15I4 birds remained relatively constant over a 30-day period. The presence of two 7S Ig populations in 15I4 chickens may be interpreted as evidence either for 7S Ig subclasses with shared allotypes or for a pseudoallelic organization of genes controlling expression of 7S Ig H chains. The results were consistent with the presence of redundant C region genes, differing in allotypes, whose expression is under the control of an as yet undefined regulatory mechanism.     

Homology between avian oncornavirus RNAs and DNA from several avian species.

3H-labeled 35S RNA from avian myeloblastosis virus (AMV), Rous associated virus (RAV)-0, RAV-60, RAV-61, RAV-2, or B-77(w) was hybridized with an excess of cellular DNA from different avian species, i.e., normal or leukemic chickens, normal pheasants, turkeys, Japanese quails, or ducks. Approximately two to three copies of endogenous viral DNA were estimated to be present per diploid of normal chicken cell genome. In leukemic chicken myeloblasts induced by AMV, the number of viral sequences appeared to have doubled. The hybrids formed between viral RNA and DNA from leukemic chicken cells melted with a Tm 1 to 6 C higher than that of hybrids formed between viral RNA and normal chicken cell DNA. All of the viral RNAs tested, except RAV-61, hybridized the most with DNA from AMV-infected chicken cells, followed by DNA from normal chicken cells, and then pheasant DNA. RAV-61 RNA hybridized maximally (39%) with pheasant DNA, followed by DNA from leukemic (34%), and then normal (29%) chicken cells. All viral RNAs tested hybridized little with Japanese quail DNA (2 to 5%), turkey DNA (2 to 4%), or duck DNA (1%). DNA from normal chicken cells contained only 60 to 70% of the RAV-60 genetic information, and normal pheasant cells lacked some RAV-61 DNA sequences. RAV-60 and RAV-61 genomes were more homologous to the RAV-0 genome than to the genome of RAV-2, AMV, or B-77(s). RAV-60 and RAV-61 appear to be recombinants between endogenous and exogenous viruses.     

Genetic regulation of CFA expression in interspecific avian hybrids and somatic cell hybrids

Chicken fetal-leukemic antigen (CFA) is an oncodevelopmental antigen present on embryonic and neonatal chicken peripheral red blood cells (RBCs) but is not restricted to fetal stages of development in other avian species. Crosses between white Leghorn chickens and Japanese quail resulted in adult hybrids whose peripheral RBCs were positive for CFA. Of the four CFA determinants normally found in adult quail RBCs, only two were present on quail-chicken hybrid RBCs. Adult quail--chicken hybrid RBCs also possessed on CFA determinant associated with early development in both quail and chicken and one chicken-specific CFA determinant. Evidence is presented for the possible association of CFA-positive adult peripheral RBCs and the level of circulating reticulocytes. Crosses between pheasant and turkey (both with CFA-positive adult RBCs) resulted in hybrid adult RBCs expressing only a portion of the parental CFA determinants. Through the formation of somatic cell hybrids between adult chicken and embryonic Japanese quail RBCs, it was possible to induce the appearance of CFA determinants normally restricted to embryonic chicken RBCs. Approximately 50% of the hybrid cells showed reexpression of CFA, and this induction was both time and temperature dependent. Hybridization between RBCs of adult chicken and those of either adult Japanese quail or adult turkey failed to elicit the reexpression of chicken-specific CFA.     

Structural and genetic studies on chicken 7S immunoglobulin allotypes. II. Distribution of allotypes on the 7S immunoglobulin of homozygous and heterozygous chickens.

We have previously reported that chicken 7S immunoglobulin (Ig) heavy (H) chain allotypes (CS-1 locus) segregate as phenogroups in F2 progeny. Specificity CS-1.1 formed a phenogroup with CS-1.4 in inbred chicken line UCD 2, and a second phenogroup with CS-1.3 in line UCD 3. To determine whether these phenogroups were formed by combinations of specificities on the same, or on separate subclasses of 7S Ig, their distribution on the 7S Ig molecules of birds homozygous for 7S Ig allotypes was analyzed by radioimmunoassay. Anti-CS-1.1 and anti-CS-1.3 alloantisera each bound more than 94% of line UCD 3 1252-7S Ig. Similar results were obtained with alloantisera to CS-1.1 and CS-1.4 WITH 125 I-7S Ig from line UCD 2. These results indicate that both phenogroups were formed by combinations of specificities present on the same H chain. Thus, each phenogroup described, probably is the product of a single structural gene which is responsible for more than 94% of the 7S Ig H chain constant regions. In F hybrids with the genotype CS-1.3, 1.3/CS-1.2, two populations of serum 7S Ig molecules were detected by direct and sequential binding analysis with specific alloantisera. One population of 7S Ig contained specificities CS-1.1 AND CS-1.3, but not CS-1.2; while the second population was exclusively the product of one parental allele. Consistent with a genetic regulatory mechanism involving allelic exclusion, no MS Ig containing allotypes produced by both alleles was detected.     

An allotypic marker on chicken immunoglobulin light chains.

The first chicken immunoglobulin light (L) chain allotypic specificity (L-1.1) to be described that was present on IgM, 7S Ig, Fab, and L chains was detected by radioimmunoassay. The gene controlling the expression of L-1.1 is inherited in a simple Mendelian fashion at an autosomal locus and is unlinked to a constant region heavy chain locus, four blood group loci and three loci determining lymphocyte cell surface alloantigens.     

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.     

Structural and genetic studies on chicken 7S immunoglobulin allotypes. III. Proposed nomenclature for the CS-1 gene alleles.

A survey of 47 inbred or partially inbred chicken lines derived from five sources in the United States and Europe revealed considerable genetic polymorphism in the structural gene (CS-1) responsible for the production of the predominant chicken 7S Ig heavy chain. A minimum of 10 alleles of the CS-1 gene were detected as unique combinations or phenogroups of CS-1 specificities. A system of nomenclature for CS-1 alleles was developed and six homozygous lines were designated as prototype lines. The remaining four CS-1 alleles occurred only in lines that were polymorphic for 7S Ig allotypic specificities.     

Structural and genetic analysis of four chicken 7S immunoglobulin allotypes

Four 7S immunoglobulin allotypic specificities in three inbred chicken lines were demonstrated in two immunoglobulin regions, probably associated with the heavy chains. Two specificities were associated with papain-produced Fab fragments, most likely the Fd fragment since they were not demonstrated on the 17S immunoglobulin. The other allotypes were detected only on intact 7S immunoglobulin and were undetectable on the Fab and Fc fragments; therefore, they probably were associated with a region of the heavy chain sensitive to papain digestion. Among F₂ hybrids, these specificities segregated in a manner statistically indistinguishable from that expected of three codominant alleles at an autosomal locus. This locus was not closely associated with any of five chicken blood group loci.     

Comparative cytological study of Phasianus colchicus,Meleagris gallopavo,and Gallus domesticus

Summary Since viable intergeneric hybrids between the chicken (Gallus domesticus) and the pheasant (Phasianus colchicus) have been reported, as well as interfamilial hybrids between the chicken and the turkey (Meleagris gallopavo), the chromosome complements of the pheasant and the turkey were compared with that of the chicken. In these three species belonging to the order Galli, the Z-chromosomes appeared to be identical, while the autosomal complements of the pheasant and the turkey differed radically from that of the chicken. It was noted with some surprise that the pheasant of the family Phasianidae and the turkey of the family Meleagridae have very similar chromosome complements, at least so far as gross morphology of somatic metaphase chromosomes is concerned.This work was supported in part by grant C-5138 from the National Cancer Institute, U.S. Public Health Service, and grant C-17601 from the National Science Foundation.The authors gratefully acknowledge the generosity of Rea's Game Birds, Paramount, California, who supplied the pheasant chicks, and the McPherin Hatcheries, Sunnymead, California, who furnished the turkey chicks. The authors also appreciate the editorial assistance of'Patricia A. Ray.     

Surface immunoglobulin on rabbit lymphoid cells. III. Double expression and separate endocytosis of surface immunoglobulin allotypes on heterozygous lymphocytes demonstrated by immunoelectron microscopic labeling.

The expression of immunoglobulin b locus (k chain) allotypes on the surface of rabbit peripheral blood lymphocytes (PBL's) is examined using an indirect double immunoelectron microscopic labeling technique. Ferritin and whelk hemocyanin individually conjugated to allotypically specific IgG are used as ultrastructurally identifiable molecular markers. These indicators are coupled to lymphocyte surface immunoglobulin (Ig) allotypic determinants by an antiallotype antibody linkage. Human red blood cells, conjugated with IgG of a specific allotype and used as test cells, demonstrate the absolute specificity and high efficiency of the ultrastructural labeling technique. Specific labeling on rabbit PBL's shows that 65–75% of the cells are positive for surface Ig. Lymphocytes from homozygous donors (b4b4 or b6b6) are labeled specifically with only the appropriate allotypic labeling system. Thirty-three percent of the PBL's from heterozygous donors (b4b6) express both allotypes (allelic inclusion) on the cell surface; the remaining proportion of Ig-bearing cells have only one detectable allotype present (allelic exclusion). We conclude that approximately 50% of the Ig-bearing PBL's demonstrate allelic inclusion for the b locus allotypes. On allelically included heterozygous lymphocytes, both allotypic determinants can undergo specific endocytosis. Endocytosis of one allotype on heterozygous cells can be induced by stimulation with antiallotypic serum without affecting the surface appearance of the other allelic marker (separate endocytosis).     

Studies on comparative drug metabolism by hepatic cytochrome P-450-containing microsomal enzymes in quail, ducks, geese, chickens, turkeys and rats

1. These studies were carried out to compare certain hepatic microsomal drug-metabolizing enzymes of quail, ducks, geese, chickens, turkeys and rats. 2. Comparison of relative liver weights of the species indicated that the rats had the largest weight followed by turkeys, ducks, geese, chickens and quail. 3. Rats ranked highest in hepatic cytochrome P-450 content followed in decreasing order by turkeys, geese, chickens, ducks and quail. 4. Microsomal benzphetamine N-demethylase activity was significantly higher in geese and turkeys than that for the rest of the species. 5. Geese, chickens and turkeys showed similar aniline hydroxylase activity, while it was markedly lower in quail and ducks with rats being intermediate.     

Differential regulation of MMPs and matrix assembly in chicken and turkey growth-plate chondrocytes

Matrix metalloproteinases (MMPs) play a crucial role in growth-plate vascularization and ossification by processes involving proteolytic cleavage and remodeling of the extracellular matrix (ECM). Their regulation in the growth plate is crucial for normal vs. impaired matrix assembly. Tibial dyschondroplasia (TD), a prevalent skeletal abnormality in avian species, is characterized by the formation of a nonvascularized, nonmineralized plaque in the growth plate. Here, we show differential regulation of MMPs in cultured chondrocytes from chickens and turkeys; retinoic acid (RA) elevated MMP-2 activity in both species, but only in chicken did it induce MMP-9 activity. In contrast, phorbol 12-myristate 13-acetate (PMA) treatment induced MMP-9 activity in turkey chondrocytes but not in those of chicken. Moreover, we found different developmental patterns of TD in chickens and turkeys in-vivo as lower concentrations of, and shorter exposure to thiram were required in chicken than in turkey for TD induction. Growth-plate cartilage taken from thiram-induced lesions had lower gelatinolytic and caseinolytic activities compared with normal cartilage. Likewise, thiram reduced MMP-2 and MMP-13 activity in both chicken and turkey chondrocytes in vitro, although 10-fold higher concentrations were required for this effect in the latter. Finally, the combined treatments of RA or PMA with thiram induced MMP-9 activity in turkey but not in chicken chondrocytes. Furthermore, RA combined with thiram synergistically upregulated its activity in turkey but not chicken chondrocytes. Taken together, these results suggest that mechanisms of MMP regulation differ in the growth plates of these closely related avian species, resulting in altered matrix assembly as exemplified by TD development.     

Extraintestinal sporozoites of chicken Eimeria in chickens and turkeys

Oocysts were found in the feces of chickens (recipients) dosed orally with whole blood, liver, lung, or heart homogenates from chickens and turkeys (donors) inoculated 3 and 4 days previously with a mixture of 3.5 X 10(6) oocysts of chicken Eimeria. No oocysts were found in the feces of recipients given spleen homogenates from these same chickens and turkeys and none were found in the feces of recipients given similar material from uninoculated donors. Intracellular sporazoites were found in the peripheral blood of a turkey inoculated with chicken Eimeria. The results indicate that a small number of sporozoites are capable of invading and surviving for at least 4 days in the peripheral blood of chickens and turkeys.     

Allantoin,the oxidation product of uric acid is present in chicken and turkey plasma

Urate oxidase is not present in birds yet allantoin, a product of this enzyme, has been measured in birds. Studies were designed to compare the concentrations of plasma purine derivatives in chickens and turkeys fed inosine-supplemented diets. The first study consisted of 12 male chicks that were fed diets supplemented with 0.6 mol inosine or hypoxanthine per kilogram diet from 3- to 6-week-old. Study 2 consisted of 12 turkey poults (toms) fed inosine-supplemented diets (0.7 mol/kg) from 6- to 8-week-old. Plasma allantoin and oxypurines concentrations were measured weekly using high performance liquid chromatography. Plasma uric acid (PUA) in chickens fed inosine-supplemented diets increased from 0.31 to 1.34 mM (P<0.05) at the end of week 2. In turkeys, those fed control diet had 0.17 mM PUA concentration compared to 0.3 mM in those fed the inosine diet at week 2 (P<0.05). Allantoin concentration increased in chickens from week 1 to 2 while a decrease was observed in turkeys (P<0.005) for both treatments. These data show that allantoin is present in turkey and chicken plasma. The presence of allantoin in avian plasma is consistent with uric acid acting as an antioxidant in these species.     

Recombinant-derived chicken growth hormone used for radioimmunoassay

The use of recombinant-derived chicken growth hormone (rcGH) in an avian growth hormone (GH) radioimmunoassay (RIA) procedure is described. Antiserum to turkey GH bound 125I-labeled rcGH, and unlabeled rcGH or turkey GH displaced binding in a dose-related manner. The dose-response curves of sera and pituitary extract from chickens and turkeys were parallel to the rcGH standard curve. Sera from hypophysectomized (hypox) chickens and turkeys produced no dose-response and did not inhibit binding of labeled rcGH. Recovery of rcGH added to hypox sera was quantitative. Modification of the homologous turkey GH RIA protocol of Proudman and Wentworth (1) to use rcGH made possible either an increase in assay sensitivity or a 3-day reduction in incubation time.     

The occurrence of uridine diphosphate N-acetylgalactosamine 6-sulfate in quail egg white and characteristic distribution of sulfated sugar nucleotides in different avian eggs

A sulfated sugar nucleotide has been isolated from quail egg white, and accounts for nearly 80% of the total sugar nucleotides found in the egg white. Evidence is presented that this nucleotide is uridine diphosphate N-acetylgalactosamine 6-sulfate, an isomer of the 4-sulfated derivative of uridine diphosphate N-acetylgalactosamine previously found in chicken egg white. Further studies on the distribution of sulfated sugar nucleotides in egg white of various birds (chicken, quail, pheasant, peafowl, turkey, goose, and duck) demonstrate that each species has a characteristic composition, differing from one another regarding the relative amounts of 4-sulfated, 6-sulfated, and 4,6-bissulfated derivatives of uridine diphosphate N-acetylgalactosamine.     

Eimeria tenella,Eimeria necatrix, and Eimeria adenoeides: Peripheral blood leukocyte response of chickens and turkeys to strains adapted to the turkey embryo

The peripheral blood leukocyte responses of chickens and turkeys inoculated with one of three strains of a chicken Eimeria species adapted to the turkey embryo with their respective parent lines, or with E. adenoeides of the turkey were studied. The adapted lines tended to cause hematological changes in chickens and turkeys similar to those caused by E. adenoeides. These parasites caused the most significant increases in large mononuclear white blood cells = (monocytes) in both chickens and turkeys. These results provide further evidence for a monocyte/macrophage effector mechanism in the rejection of heterologous species of Eimeria from a nonspecific host. The results also agree with previous studies that show that increases in mononuclear white blood cells during parent E. tenella and E. necatrix infections in chickens occur during the periods of greatest tissue damage (3–4 days after inoculation). The generally unaffected lymphocyte numbers and increases in mononuclear white blood cells during infections with the adapted lines probably explain the reduced pathogenicity and the lack of immunogenicity seen previously in chickens inoculated with these three lines. Possibly, monocytes/macrophages play a role in the host specificity of the parasites.