Surface of the rooster spermatozoon changes in passing through the Wolffian duct

Fluid secreted by the rooster Wolffian duct contains several proteins separable on polyacrylamide gel electrophoresis (PAGE) and isoelectric focusing (IEF) gels. Antibodies against these fluid components were obtained by immunizing rabbits, and the IgG fraction was then purified. As judged by indirect immunofluorescence, purified IgG against rooster duct fluid did not bind to any testicular spermatozoa. However, it bound distinctly to the whole surface of spermatozoa from the initial (epididymal) region and more intensely to all spermatozoa from the mid- and terminal regions of the Wolffian duct of the rooster, though not at all to mature duck or pigeon spermatozoa. Thus, in the rooster, as in therian mammals, the surface of the spermatozoon clearly acquires specific components secreted by the Wolffian duct. It should not be assumed that such surface change in rooster spermatozoa is entirely comparable, in a functional sense, to that undergone by mammalian spermatozoa, in which this seems directly related to fertilizing ability. Unlike those of mammals, rooster spermatozoa do not seem to require capacitation, and some spermatozoa in the testis already are competent to fertilize. Components acquired in the Wolffian duct by the rooster spermatozoon may bear on other aspects, perhaps sperm transport and/or survival in the female.     

Post-testicular change in the reptile sperm surface with particular reference to the snake, Natrix fasciata

Sperm surface changes occurring in the reptile Wolffian duct have been explored with particular references to the snake, Natrix fasciata. In the snake Wolffian duct there are several proteins not present in serum, the pattern of which changes in concert with the seasonal testicular cycle. Whereas testicular spermatozoa did not bind antibody to duct secretions, all Wolffian duct spermatozoa did so over both head and tail, according to immunofluorescence patterns. Thus, on entering the Wolffian duct, the entire surface of N. fasciata spermatozoa acquires one of more of the duct's secretory components. As indicated by immunofluorescence, immunoelectrophoresis, and immunodiffusion, epitopes on at least some molecules that bind to spermatozoa or that remain free in the duct fluid are shared with those in other Natrix species, but not in more distant reptiles (turtle, anole lizard), nor chicken, rat, or rabbit. In regard to glycoproteins, one prominent con A-reactive band was present in polyacrylamide gel electrophoresis (PAGE) of snake fluid and more were evident in fluid collected from the turtle duct. However, such lectin-reactive elements did not bind to spermatozoa as judged by an absence of any change in snake, turtle and lizard sperm lectin-binding patterns in passing from the testis into and through the Wolffian duct. In all, evidence from these and other species studied begins to suggest that the nature of the post-testicular sperm surface modification displayed in most vertebrates that fertilize internally may differ in sub-therian and therian groups, respectively. There appears to be a relative emphasis on glycosyl-rich surface elements in the latter. The possible significance of these changes for sperm function in the different groups is discussed briefly in terms of sperm survival/storage, as well as capacitation and sperm binding to the zona.     

Immunohistochemistry of the cytoskeleton in the excurrent ducts of the testis in birds of the Galloanserae monophyly

The presence, location and degree of immunoexpression of various microfilament (MF) and intermediate filament (IF) systems (actin, cytokeratins, desmin, vimentin) were studied in the excurrent ducts of the testis in sexually mature and active galliform (Japanese quail, domestic fowl, turkey) and anseriform (duck) birds. These proteins were variably expressed between the epithelia and periductal tissue (periductal smooth muscle cell layer and interductal connective tissue) types and between species. Variable heterogeneous co-expression of filament systems was also found in the various duct epithelia and periductal tissue types: co-expression of filament systems was the rule rather than the exception. In the duck, neither vimentin nor cytokeratin was present in any of the tissues, whereas actin and desmin (absent in the rete testis) were co-expressed in the efferent ducts and epididymal duct unit (comprising the ductus conjugens, ductus epididymidis and ductus deferens). Actin, desmin and vimentin were generally co-expressed in the rete testis, efferent ducts and epididymal duct unit of the quail, domestic fowl and turkey, with vimentin being more strongly immunoreactive than actin and desmin in the epididymal duct unit, but more weakly immunoexpressed in the efferent ducts. Cytokeratin was present and co-expressed with actin, desmin and vimentin in the rete testis, efferent ducts and epididymal duct unit of the domestic fowl and turkey, but not in the quail and duck. The periductal smooth muscle cell layer and interductal tissue co-expressed actin, desmin and vimentin variably in all birds. Luminal spermatozoa of both the turkey and duck were immunonegative for all protein systems, whereas those of the quail and domestic fowl co-expressed actin, desmin and vimentin moderately or strongly. The tissues of the reproductive tract of male birds thus contain cytoskeletal protein systems that are variably but mostly co-expressed and whose contractile ability appears necessary and sufficient for transportation through the various excurrent ducts of the voluminous testicular fluid and its high sperm content, characteristic features of male avian reproduction.     

Segmental and cellular expression of aquaporins in the male excurrent duct

The male reproductive tract and accessory glands comprise a complex but interrelated system of tissues that are composed of many distinct cell types, all of which contribute to the ability of spermatozoa to carry out their ultimate function of fertilizing an oocyte. Spermatozoa undergo their final steps of maturation as they pass through the male excurrent duct, which includes efferent ducts, the epididymis and the vas deferens. The composition of the luminal environment in these organs is tightly regulated. Major fluid reabsorption occurs in efferent ducts and in the epididymis, and leads to a significant increase in sperm concentration. In the distal epididymis and vas deferens, fluid secretion controls the final fluidity of the luminal content. Therefore, the process of water movement in the excurrent duct is a crucial step for the establishment of male fertility. Aquaporins contribute to transepithelial water transport in many tissues, including the kidney, the brain, the eye and the respiratory tract. The present article reviews our current knowledge regarding the distribution and function of aquaporins in the male excurrent duct.     

Segmental and cellular expression of aquaporins in the male excurrent duct

The male reproductive tract and accessory glands comprise a complex but interrelated system of tissues that are composed of many distinct cell types, all of which contribute to the ability of spermatozoa to carry out their ultimate function of fertilizing an oocyte. Spermatozoa undergo their final steps of maturation as they pass through the male excurrent duct, which includes efferent ducts, the epididymis and the vas deferens. The composition of the luminal environment in these organs is tightly regulated. Major fluid reabsorption occurs in efferent ducts and in the epididymis, and leads to a significant increase in sperm concentration. In the distal epididymis and vas deferens, fluid secretion controls the final fluidity of the luminal content. Therefore, the process of water movement in the excurrent duct is a crucial step for the establishment of male fertility. Aquaporins contribute to transepithelial water transport in many tissues, including the kidney, the brain, the eye and the respiratory tract. The present article reviews our current knowledge regarding the distribution and function of aquaporins in the male excurrent duct.     

Temperature-dependent inhibition of motility in spermatozoa from different avian species

This study demonstrates that the pattern of temperature-dependent inhibition of chicken sperm motility at 40 degrees C in vitro, and its release by calcium, is also found in drake spermatozoa and, partially, in turkey spermatozoa. However, no such temperature-dependent inhibition was found in spermatozoa from Japanese quail and Houbara bustard, for which physiological levels of calcium at 40 degrees C had an inhibitory and no effect on sperm motility, respectively. Thus, on the basis of this evidence on the regulation of avian sperm motility in vitro, the hypothesis that oviducal sperm storage tubules might immobilise spermatozoa by providing a calcium-free environment in vivo does not appear to be universally applicable to all species of birds.     

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.     

Integration of human mesenchymal stem cells into the Wolffian duct in chicken embryos

Developing animal embryos have been providing human mesenchymal stem cells (hMSCs) with an appropriate environment for their differentiation between species. We previously demonstrated that hMSCs transplanted into the metanephric mesenchyme region of rat embryos differentiate into kidney-specific cells. Here, we assessed whether hMSCs are competent to differentiate into precursors of the collecting duct system when they are transplanted into the ureteric bud progenitor region of chicken embryos that are easier to be manipulated and cultured than mammalian embryos. When chicken Pax2-expressing hMSCs were transplanted into the chicken ureteric bud progenitor region, they migrated caudally with the elongating Wolffian duct and then were integrated into the Wolffian duct epithelia. Also, chicken Pax2-expressing hMSCs started to express human LIM1 after their integration into the Wolffian duct epithelia. These results suggest that chicken Pax2-expressing hMSCs can be competent to differentiate into the Wolffian duct cells by the influence of chicken local signals.     

Distribution of the Galβ1-4Gal Epitope among Birds: Species-Specific Loss of the Glycan Structure in Chicken and Its Relatives

The Galβ1-4Gal epitope is rarely found in mammals, and the natural antibody against Galβ1-4Gal is rich in human. In contrast, we have previously demonstrated the presence of Galβ1-4Gal in pigeon and ostrich, and the absence of this epitope in chicken. Here, to further investigate the expression of this glycan among birds, egg white glycoproteins and egg yolk IgG from nine species of birds, namely, chicken, duck, emu, guineafowl, ostrich, peafowl, pigeon, quail, and turkey, were analyzed by western blot using an anti-(Galβ1-4Gal) antibody. The results indicated that some egg white glycoproteins from emu, ostrich, and quail, and heavy chains of IgG from all of the birds, except chicken and quail, were stained with the antibody. The presence of Galβ1-4Gal on N-glycans of IgGs from guineafowl, peafowl, and turkey were confirmed by mass spectrometry (MS), MS/MS, and MSⁿ analyses. In quail, the presence of Galβ1-4Gal was confirmed by detecting the activities of UDP-galactose: β-galactoside β1,4-galactosyltransferase (β4GalT(Gal)) in various tissues, and by detecting Galβ1-4Gal by western blotting. In contrast, bamboo partridge, which is a close relative of chicken, did not show any detectable activities of β4GalT(Gal) or Galβ1-4Gal on glycoproteins. Because quail, peafowl, turkey, chicken, and bamboo partridge belong to the same family, i.e., Phasianidae, expression of Galβ1-4Gal was most likely differentiated within this family. Considering that Galβ1-4Gal is also expressed in ostrich, emu, and pigeon, which are phylogenetically distant relatives within modern birds, Galβ1-4Gal expression appears to be widely distributed among birds, but might have been abolished in the ancestors of chicken and bamboo partridge.     

Evidence for a species-specific barrier to sperm transport within the vagina of the chicken hen

Following their insemination into the vagina of chicken hens, turkey spermatozoa did not appear to reach the ovum within the upper magnum or infundibulum and were only occasionally found within the sperm storage tubules at the uterovaginal junction. Turkey spermatozoa were able to populate chicken uterovaginal sperm storage tubules as (or more) efficiently as fowl spermatozoa in uterovaginal junction tissue in vitro. They also populated uterovaginal junction sperm storage tubules in vivo after insemination directly into the uterovaginal region. Thus, a barrier to foreign spermatozoa appears to exist within the vagina of the chicken and not at the level of the uterovaginal junction sperm storage tubules. The nature of this barrier is not known; however it can be shown that while chicken and turkey spermatozoa have similar morphological features and motility characteristics, they have distinct surface antigenicity. Recognition of surface antigenicity by a localised immunological mechanism may be the basis of sperm selection within the hens vagina.     

Insertion events of CR1 retrotransposable elements elucidate the phylogenetic branching order in galliform birds

Using standard phylogenetic methods, it can be hard to resolve the order in which speciation events took place when new lineages evolved in the distant past and within a short time frame. As an example, phylogenies of galliform birds (including well-known species such as chicken, turkey, and quail) usually show low bootstrap support values at short internal branches, reflecting the rapid diversification of these birds in the Eocene. However, given the key role of chicken and related poultry species in agricultural, evolutionary, general biological and disease studies, it is important to know their internal relationships. Recently, insertion patterns of transposable elements such as long and short interspersed nuclear element markers have proved powerful in revealing branching orders of difficult phylogenies. Here we decipher the order of speciation events in a group of 27 galliform species based on insertion events of chicken repeat 1 (CR1) transposable elements. Forty-four CR1 marker loci were identified from the draft sequence of the chicken genome, and from turkey BAC clone sequence, and the presence or absence of markers across species was investigated via electrophoretic size separation of amplification products and subsequent confirmation by DNA sequencing. Thirty markers proved possible to type with electrophoresis of which 20 were phylogenetically informative. The distribution of these repeat elements supported a single homoplasy-free cladogram, which confirmed that megapodes, cracids, New World quail, and guinea fowl form outgroups to Phasianidae and that quails, pheasants, and partridges are each polyphyletic groups. Importantly, we show that chicken is an outgroup to turkey and quail, an observation which does not have significant support from previous DNA sequence- and DNA-DNA hybridization-based trees and has important implications for evolutionary studies based on sequence or karyotype data from galliforms. We discuss the potential and limitations of using a genome-based retrotransposon approach in resolving problematic phylogenies among birds.     

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.     

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.     

Role of prostaglandins in the testosterone-dependent wolffian duct differentiation of the fetal mouse.

Recent observations from this laboratory indicated a role of prostaglandin E2 (PGE2) in masculine differentiation of the external genitalia of the fetal mouse, induced by fetal testosterone. In this communication, we further investigated the role played by PGE2 in the testosterone-induced differentiation of the internal genital tract (Wolffian duct) of the fetal mouse. Using in vitro organ culture bioassay of Wolffian duct differentiation, we determined the effect of a PG-depleting agent, namely, anti-PGE2 antibody, and of inhibitors of PG synthesis for their ability to prevent Wolffian duct differentiation in the presence of testosterone. We demonstrated that anti-PGE2 antibody inhibited Wolffian duct differentiation in a dose-dependent manner in embryonic male explants containing fetal testes. At 1:10 dilution, the antibody inhibited the appearance of the entire Wolffian duct as well as growth of the specimen. At 1:100 dilution, however, only development of the Wolffian duct was prevented, as indicated by the absence of regions of the Wolffian duct or by the presence of epithelial disintegration throughout the ductal lumen. The antibody at 1:1000 dilution produced no significant effect on the appearance of the Wolffian duct. PGE2 (10 micrograms/ml) replacement in the medium prevented Wolffian duct disintegration induced by anti-PGE2. We next determined whether the testosterone-dependent Wolffian duct differentiation requires ongoing PG synthesis within the reproductive tract and analyzed the effects of the compounds inhibiting PG synthesis at the level of phospholipase A2 (PLA2) namely, cortisone and dexamethasone-and of those inhibiting at the level of cyclooxygenase-namely, aspirin and indomethacin. We have demonstrated that both PLA2 and cyclooxygenase inhibitors inhibited Wolffian duct differentiation in the male explant, i.e., in the presence of testis. These compounds also prevented the appearance of the Wolffian duct in female explants induced by exogenous testosterone. PGE2 added in the medium blocked the anti-masculinizing effects of PG synthesis inhibitors both in the male and female specimens. Thus, it appears that PG synthesis plays a role in the testosterone-induced masculine differentiation of the Wolffian duct.     

Spermatozoa transport in the oviduct of the chicken and the turkey

Recent studies of the storage and release of spermatozoa from utero-vaginal glands in birds have shown that: following intra-vaginal insemination, storage is completed within 2-3 d (domestic hen) or 1-5 d (turkey) and not within a few minutes or hours as previously described; as spermatozoa can be recovered from any segment of the oviduct during the egg formation cycle, it seems unlikely that sperm release from the utero-vaginal glands is directly dependent upon the egg formation cycle. The progressive inability of spermatozoa to agglutinate may be part of this mechanism.     

Storage of spermatozoa in the oviducts of birds: morphologic, histologic and functional approach

This paper reviews the studies devoted to the anatomical, histological and functional aspects of sperm storage in the oviduct of domestic birds (hen, turkey). Despite the presence of substances, such as lipids and mucopolysaccharides, in the cytoplasm of the cells encompassing the utero-vaginal glands (site of residence of spermatozoa in the oviduct after intra-vaginal inseminations), the absence of organelles involved in protein synthesis questions the existence of a secretory cycle in these glands. In the absence of such a cycle, the microvilli bordering the lumen of the utero-vaginal glands could participate in the purification of this micro-environment, thus allowing prolonged survival of spermatozoa in this region. Recent observations indicate that the mechanism controlling the penetration and/or storage of spermatozoa in the utero-vaginal glands is of an immuno-dependent nature and is closely related to the functional integrity of the glycocalyx surrounding the spermatozoon. A quantitative study of the kinetics of the storage of spermatozoa with or without alteration of their glycocalyx might help to explain its role (recognition of spermatozoa by the utero-vaginal glands or agglutination of spermatozoa within these glands). This type of experiment might also contribute to understanding the mechanism underlying the prolonged storage of spermatozoa in the utero-vaginal glands of birds.     

DNase I and II present in avian oocytes: a possible involvement in sperm degradation at polyspermic fertilisation

During polyspermic fertilisation in birds numerous spermatozoa enter the eggs, in contrast to the situation in mammals where fertilisation is monospermic. However, in birds only one of the spermatozoa which have entered an egg participates in zygote nucleus formation, while the supernumerary spermatozoa degenerate at early embryogenesis. Our previous work has demonstrated the presence in preovulatory quail oocytes of DNase I and II activities able to digest naked lambdaDNA/HindIII substrate in vitro. In the present studies, the activities of both DNases in quail oocytes at different stages of oogenesis and in ovulated mouse oocytes were assayed in vitro using the same substrate. Degradation of quail spermatozoa by quail oocyte extracts was also checked. Digestion of the DNA substrate was evaluated by electrophoresis on agarose gels. The activities of DNase I and II in quail oocytes increased during oogenesis and were the highest in mature oocytes. The activities were present not only in germinal discs but also in a thin layer of cytoplasm adhering to the perivitelline layer surrounding the yolk. At all stages of oogenesis the activity of DNase II was much higher than that of DNase I. DNA contained in spermatozoa was also degraded by the quail oocyte extracts under conditions optimal for both DNases. In contrast to what is observed in quail oocytes, no DNase activities were detected in ovulated mouse eggs; this is logical as they would be useless or even harmful in monospermic fertilisation. The possible role of DNase activities in avian oocytes, in degradation of accessory spermatozoa during polyspermic fertilisation, is discussed.     

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.     

Development and characterization of expressed sequence tags for the turkey (Meleagris gallopavo) genome and comparative sequence analysis with other birds

Twenty-one randomly selected clones from a turkey (Meleagris gallopavo) pituitary complementary DNA (cDNA) library were sequenced to develop expressed sequence tags (ESTs) for this economically important avian species whose genome is among the least understood. Primers specific for the ESTs were used to produce amplicons from the genomic DNA of turkey, chicken (Gallus gallus), guinea fowl (Numidia meleagris), pigeon (Columba domestica), and quail (Corturnix japonica). The amplicons were sequenced and analyzed for sequence variation within- and similarity among-species and with GenBank database sequences. The proportion of shared bases between the turkey sequence and the consensus sequence from each of the other species ranged from 72% to 93% between turkey and pigeon and quail and between turkey and chicken, respectively. The total number of single nucleotide polymorphisms (SNPs) observed ranged from 3 in quail to 18 in chicken out of 4898 and 5265 bases analyzed, respectively. The most frequent nucleotide variation observed was a C-->T transition. Linkage analysis of one such SNP in the backcross progeny of the East Lansing reference DNA panel, localized TUS0005, the chicken sequence derived from primers specific for turkey TUT2E EST, to chromosome 4. The ESTs reported, as well as the SNPs may provide a useful resource for ongoing efforts to develop high utility genome maps for the turkey and chicken. The primers described can also be used as a tool in future investigations directed at further understanding the biology of the guinea fowl, pigeon and quail and their relatedness to the turkey.     

Expression analysis of turkey (Meleagris gallopavo) toll-like receptors and molecular characterization of avian specific TLR15

Toll-like receptors (TLRs) constitute a multi-gene family, which plays a pivotal role in sensing invading pathogens by virtue of conserved microbial patterns. TLR repertoire of chicken and zebra finch has been well studied. However TLR family of other avian species is yet to be characterized. In the present study, we identified TLR repertoire of turkey, characterized avian specific receptor TLR15 in turkey and profiled the TLRs expressions in a range of tissues of turkey poults. All ten TLR genes orthologous to chicken TLR repertoire were found in turkey. Turkey TLR genes showed 81-93 % similarity at amino acid level to their chicken counter parts. Phylogenetic analysis confirmed the orthologous relationship of turkey TLRs with chicken and zebra finch TLRs. Open reading frame of turkey TLR15 was 2,607 bp long encoding 868 amino acids similar to that of broiler chicken and showed 92.4, 91.1 and 69.5 % identity at amino acid levels with chicken, Japanese quail and zebra finch TLR15 sequences respectively. Overall TLR expression was highest for TLR4 and lowest for TLR21. TLR1A, 2A, 2B and 21 were significantly higher in liver than other tissues investigated (P < 0.01). TLR3 expression was significantly higher in bone marrow (BM) and spleen in comparison to other tissues studied (P < 0.01). Furthermore, no significant differences in the expression levels of TLR1B, 4, 5, 7 and 15 genes were detected among the tissues studied. Our findings contribute to the characterization of innate immune system of birds and show the innate preparedness of young turkey poults to a range of pathogens.