Design and Development of a Novel Peptide for Treating Intestinal Inflammation

Intestinal inflammatory disorders, such as inflammatory bowel disease (IBD), are associated with increased pro-inflammatory cytokine secretion in the intestines. Furthermore, intestinal inflammation increases the risk of enteric cancer, which is a common malignancy globally. Native anti-inflammatory peptides are a class of anti-inflammatory agents that could be used in the treatment of several intestinal inflammation conditions. However, potential cytotoxicity, and poor anti-inflammatory activity have prevented their development as anti-inflammatory agents. Therefore, in this study, we designed and developed a novel hybrid peptide for the treatment of intestinal inflammation. Eight hybrid peptides were designed by combining the active centers of antimicrobial peptides, including LL-37 (13-36), YW12D, innate defense regulator 1, and cathelicidin 2 (1-13) with thymopentin or the active center of thymosin alpha 1 (Tα1) (17-24). The hybrid peptide, LL-37-Tα1 (LTA), had improved anti-inflammatory activity with minimal cytotoxicity. LTA was screened by molecule docking and in vitro experiments. Likewise, its anti-inflammatory effects and mechanisms were also evaluated using a lipopolysaccharide (LPS)-induced intestinal inflammation murine model. The results showed that LTA prevented LPS-induced impairment in the jejunum epithelium tissues and infiltration of leukocytes, which are both histological markers of inflammation. Additionally, LTA decreased the levels of tumor necrosis factor-alpha, interferon-gamma, interleukin-6, and interleukin-1β. LTA increased the expression of zonula occludens-1 and occludin, and reduced permeability and apoptosis in the jejunum of LPS-treated mice. Additionally, its anti-inflammatory effect is associated with neutralizing LPS, binding to the Toll-like receptor 4-myeloid differentiation factor 2 (TLR4/MD-2) complex, and modulating the nuclear factor-kappa B signal transduction pathway. The findings of this study suggest that LTA may be an effective therapeutic agent in the treatment of intestinal inflammation.

Chemoprevention of spontaneous ovarian cancer in the domestic hen

The hen is an attractive animal model for in vivo testing of agents that thwart ovarian carcinogenesis because ovarian cancer in the domestic hen features clinical and molecular alterations that are similar to ovarian cancer in humans, including a high incidence of p53 mutations. The objective of the study was to test the potential ovarian cancer chemopreventive effect of the p53 stabilizing compound CP-31398 on hens that spontaneously present the ovarian cancer phenotype. Beginning at 79 wk of age, 576 egg-laying hens (Gallus domesticus) were randomized to diets containing different amounts of CP-31398 for 94 wk, 5 d, comprising a control group (C) (n = 144), which was fed a diet containing 0 ppm (mg/kg) of CP-31398; a low-dose treatment (LDT) group (n = 144), which was fed a diet containing 100 ppm of CP-31398; a moderate-dose treatment (MDT) group (n = 144) which was fed a diet containing 200 ppm of CP-31398; and a high-dose treatment (HDT) group (n = 144), which was fed a diet containing 300 ppm of CP-31398. Hens were killed at 174 wk of age to determine the incidence of ovarian and oviductal adenocarcinomas. Whereas the incidence of localized and metastatic ovarian cancers in the MDT and HDT groups was significantly lower (up to 77%) compared to levels in the C and LDT groups (P < 0.05), the incidence of oviductal cancer was unaffected by CP-31398. CP-31398 appears to be an effective tool for chemoprevention against ovarian malignancies, but does not appear to affect oviductal malignancies.

Production of Chick Germline Chimeras from Fluorescence-Activated Cell-Sorted Gonocytes

Modification of the chicken germline has been difficult, because it has been challenging to fractionate sufficient numbers of primordial germ cells for manipulation and implantation into developing embryos. A technique to enrich cell suspensions for primordial germ cells, using fluorescence-activated cell sorting (FACS), has recently been developed. The objective of the current study was to demonstrate that the FACS-enriched early embryonic gonocytes could fully participate in development of the germline. Therefore, cells were disassociated from stage 27 gonads, incubated with mouse anti-stage-specific embryonic antigen-1, which was detected with goat-antimouse IgM-fluorescein isothiocyanate, and the fluorescently labeled cells were sorted from the unlabeled cells using FACS. The isolated gonocyte population was injected into the blastoderm of unincubated stage X embryos, the germinal crescent of 3-d embryos, and into the circulation of stage 17 embryos that were pretreated with busulfan. Barred Plymouth Rock gonocytes were implanted exclusively into recipient White Leghorn embryos, and White Leghorn gonocytes were implanted exclusively into Barred Plymouth Rock recipient embryos. Embryos were cultured until hatch, and male putative chimeras were reared to sexual maturity. Germline chimerism was evaluated by observing feather color of the progeny. All injection methods resulted in germline chimeras demonstrating that FACS-sorted gonocytes can fully participate in development. Moreover, it was demonstrated that gonocytes isolated from stage 27 embryonic gonads can be introduced into embryos at an earlier stage of development, and the introduced gonocytes can fully participate in germline development.

Avian Germplasm Preservation: Embryonic Stem Cells or Primordial Germ Cells?

Presently, avian genetic resources are best maintained as living collections of birds. Unfortunately, these stocks have been under constant pressure to be destroyed because of the decline in the number of Poultry Science Departments and pressures to cut costs at land grant institutions. Cryopreservation of semen is often suggested as a means to bank avian germplasm. However, this is only applicable for single-gene traits and does not allow for full reconstitution of the genetics of the original line. Over the last 15 yr, advances in the manipulation of the early chick embryo, manipulation of primordial germ cells (PGC), and the culture of embryonic stem cells (ESC) suggests that cryopreservation of blastodermal cells, ESC, or PGC might offer a means to preserve the entire genome of highly selected, specialized stocks of poultry. Freezing each of these cell types is possible with varying degrees of efficiency. Similarly, the effectiveness of generating germ line chimeras using blastodermal cells, ESC, or PGC also varies greatly. Other factors that must be considered include the choice of the recipient lines to develop the germ line chimeras and the number of individuals needed to reconstitute the line. Finally, the low efficiency rate of reconstitution and the high cost associated with current technologies makes these approaches prohibitive. Significant challenges remain to be overcome before the entire genome of poultry stocks can be routinely cryoperserved and reconstituted.

Culture of chicken embryos in surrogate eggshells

The chick embryo is a classical model to study embryonic development. However, most researchers have not studied the effect of embryonic manipulation on chick hatchability. The objective of this study was to determine the effect of egg orientation and type of sealing film on the hatchability of cultured embryos. Windows were made in the small end of recipient surrogate chicken eggshells, and donor embryos were placed into the recipient eggshell for the first 3 d of incubation. Survival over the first 3 d was maximized (P < 0.05) when windowed eggs sealed with Saran Wrap were positioned with the window-end down compared with window-end up. Three-day-old cultured embryos were transferred into recipient turkey eggshells, sealed with cling film, and cultured until hatch. Water weight loss of the surrogate eggshell cultures regardless of cling film type was not significantly different from control intact eggs. The embryos cultured in turkey eggshells and sealed with Handi Wrap exhibited higher hatchability (75% +/- 10.2%) than cultures sealed with Saran Wrap (45.2% +/- 13.8%). Hatchability of control intact eggs (86.4% +/- 5.3%) was not significantly (P > 0.05) different from the hatchability of eggs sealed with Handi Wrap, which suggested that Handi Wrap was an excellent sealant for chick embryos cultured after 3 d of incubation.

Isolation of chicken primordial germ cells using fluorescence-activated cell sorting

Presently, it is difficult to undertake germ line modification of the chicken with primordial germ cells (PGC) because it has been difficult to efficiently fractionate the PGC from the total somatic cell population. The objective of this study was to develop a method that allows isolation of an enriched population of viable PGC from embryonic blood and embryonic gonadal tissue. Blood was harvested from early chick embryos (stages 13 to 15), and cells were liberated from the gonads of stage 27 chick embryos. Subsequently, viable PGC were labeled with anti-stage-specific embryonic antigen-1 (SSEA-1), which was detected with goat-anti-mouse IgM-fluorescein isothiocyanate. Fluorescently labeled cells were sorted from the unlabeled cells using fluorescence-activated cell sorting (FACS), and the identities of the PGC were confirmed using periodic acid-Schiff (PAS) staining or anti-embryonic mouse antigen-1 (EMA-1) staining followed by microscopic evaluation. Finally, PGC were sorted from somatic cells of sex-identified embryos. Less than 0.1% of the blood cell population was collected as SSEA-1-positive cells. Similarly, approximately 2% of the gonadal cell population were collected as SSEA-1-positive cells. Therefore, fewer (-1,000 to 9,000) PGC were recovered from each isolate. Placing the sorted SSEA-1-positive cells on a glass slide from a microcentrifuge tube resulted in a recovery rate of 53 to 73% relative to the number detected by FACS. Furthermore, the proportions of sorted cells that stained with PAS or anti-EMA-1 following sorting were 92+/-4% PAS positive and 94+/-1% anti-EMA-1 positive. Finally, the sorted SSEA-1-positive cells were maintained in vitro to demonstrate their viability after sorting. It was demonstrated that it is possible to label blood and gonadal chicken PGC with SSEA-1 and subsequently to sort viable SSEA-1-positive PGC from somatic cells.

Avian pluripotent stem cells

Pluripotent embryonic stem cells are undifferentiated cells capable of proliferation and self-renewal and have the capacity to differentiate into all somatic cell types and the germ line. They provide an in vitro model of early embryonic differentiation and are a useful means for targeted manipulation of the genome. Pluripotent stem cells in the chick have been derived from stage X blastoderms and 5.5 day gonadal primordial germ cells (PGCs). Blastoderm-derived embryonic stem cells (ESCs) have the capacity for in vitro differentiation into embryoid bodies and derivatives of the three primary germ layers. When grafted onto the chorioallantoic membrane, the ESCs formed a variety of differentiated cell types and attempted to organize into complex structures. In addition, when injected into the unincubated stage X blastoderm, the ESCs can be found in numerous somatic tissues and the germ line. The potential give rise to somatic and germ line chimeras is highly dependent upon the culture conditions and decreases with passage. Likewise, PGC-derived embryonic germ cells (EGCs) can give rise to simple embryoid bodies and can undergo some differentiation in vitro. Interestingly, chicken EG cells contribute to somatic lineages when injected into the stage X blastoderm, but only germ line chimeras have resulted from EGCs injected into the vasculature of the stage 16 embryo. To date, no lines of transgenic chickens have been generated using ESCs or EGCs. Nevertheless, progress towards the culture of avian pluripotent stem cells has been significant. In the future, the answers to fundamental questions regarding segregation of the avian germ line and the molecular basis of pluripotency should foster the full use of avian pluripotent stem cells.

Development of transgenic chickens expressing bacterial beta-galactosidase

Replication-defective retroviral vectors are efficient vehicles for the delivery of exogenous genes, and they may be used in the generation of transgenic animals. The replication-defective retroviral SNTZ vector carrying the lacZ gene with a nuclear localized signal was injected into the subgerminal cavity of freshly laid eggs. Subsequently, the eggs were allowed to hatch, and the chickens were screened for the lacZ gene by using the polymerase chain reaction. Eight of 15 male chickens that survived to sexual maturity contained the lacZ gene in their semen. Subsequently, these males were mated with wild-type female chickens. From one of the eight lacZ-positive G(0) males, two lacZ-positive male chickens were produced from a total of 224 G(1) progeny for a germline transmission rate of 0.89%. Both G(1) male chickens carrying the lacZ gene were mated with wild-type female chickens and 46.5% of the G(2) progeny contained the lacZ gene, which is consistent with the expected Mendelian 50% ratio for a heterozygous dominant allele. The product of the lacZ gene, nuclear localized beta-galactosidase, was expressed in primary myoblast cultures derived from G(2) chickens, and it was also expressed in whole G(2) chicken embryos.

Imprint status of M6P/IGF2R and IGF2 in chickens

Genomic imprinting is a method of gene regulation whereby a gene is expressed in a parent-of-origin-dependent fashion; however, it is hypothesized that imprinting should not occur in oviparous taxa such as birds. Therefore, we examined the allelic expression of two genes in the chicken that are reciprocally imprinted in most mammals, mannose 6-phosphate/insulin-like growth factor 2 receptor (M6P/IGF2R) and insulin-like growth factor 2 (IGF2). Single nucleotide polymorphisms were identified in these genes, and cDNA was prepared from several tissues of embryos heterozygous for these polymorphisms. Both alleles of M6P/IGF2R and IGF2 were expressed in all tissues examined by RT-PCR. Since the expression of these genes was independent of the parent from which they were inherited, we conclude that neither M6P/IGF2R nor IGF2 are imprinted in the chicken.

Examining the effects of prestorage incubation of turkey breeder eggs on embryonic development and hatchability of eggs stored for four or fourteen days

Thirty-six hundred British United Turkey hatching eggs were used in two separate trials to test whether prestorage incubation (PRESI) treatments of 0, 6, and 12 h (Trial 1) or 0, 7, and 14 h (Trial 2) could improve the hatchability of eggs stored (17 C) for 14 versus 4 d. The development of the embryos (n = 30) was staged before and after exposing eggs to the various PRESI treatments. Embryonic development was also established after storage to ascertain whether embryonic development was occurring during storage. The remaining eggs in each trial were split into three groups (n = 500) and incubated for 28 d to examine embryonic mortality and hatchability. No changes were observed in embryonic development due to egg storage. Embryos were significantly more developed as the number of PRESI h increased; therefore, embryos from different PRESI treatments were placed in storage at different stages of development. Early mortality (1 to 7 d of incubation), mortality at internal and external pipping, and hatchability of fertile eggs were significantly reduced in eggs stored for 14 versus 4 d. The various PRESI treatments did not significantly affect the mortality or hatchability of eggs stored for 4 d. However, the hatchability of eggs incubated prior to storage for 12 h and then stored for 14 d was restored to the levels reported for eggs subjected to the treatment that represents the industry norm (0 h of PRESI and 4 d storage). These results indicate that embryos of eggs stored for 14 d, which have developmentally advanced to the stage of complete hypoblast formation (PRESI for 12 h), have a survival advantage over eggs stored for 14 d that have not been subjected to any PRESI.

Expression and purification of biologically active recombinant quail stem cell factor in E. coli

Stem cell factor (SCF) is a multifunctional cytokine involved in hematopoiesis, melanogenesis and gametogenesis. Previous studies have demonstrated that avian SCF is a requirement for the proliferation and survival of various cell types in vivo and in vitro. In the current study, recombinant quail stem cell factor was produced in Escherichia coli using a prokaryotic expression system. SCF was expressed as a fusion protein with a histidine hexamer tag at the N-terminal end of the protein. Following expression, the protein was purified by affinity chromatography on the Ni-NTA column. The uninduced and induced protein lysates and the purified protein were separated by SDS-PAGE and transferred onto nitrocellulose membrane. Western blot analysis with the monoclonal antibody to the histidine tag identified SCF in the induced cell lysates and the purified sample. The recombinant SCF was approximately 22-23 kD in size. This protein was generated devoid of the signal peptide, the transmembrane domain, and the intracellular domain and, hence, resembles the soluble form of SCF. Biological activity was assayed using the in vitro survival of E12 chicken dorsal root ganglion-derived sensory neurons. The addition of recombinant quail SCF improved neuronal survival. Survival (20.6%) was the highest at the 50 ng/ml concentration of SCF. The availability of quail SCF will be a valuable tool to further resolve the function of stem cell factor in birds.

Origin of primordial germ cells in the prestreak chick embryo

The temporal and spatial pattern of segregation of the avian germline from the formation of the area pellucida to the beginning of primitive streak formation (stages VII-XIV, EG&K) was investigated using the culture of whole embryos and central and peripheral embryo fragments on vitelline membranes at stages VII-IX, immunohistological analysis of whole mount embryos and sections with monoclonal antibodies MC-480 against stage-specific embryonic antigen-1 (SSEA-1) and EMA-1, and with the culture of dispersed blastoderms at stages IX-XIV with and without on STO feeder layer. Whole embryos at intrauterine stages developed up to the formation of the primitive streak despite the absence of area pellucida expansion. Primordial germ cells (PGCs) appeared in the cultures of whole embryos and only in central fragments containing a partially formed area pellucida at stages VII-IX. When individual stage IX-XIV embryos were dispersed and cultured without a feeder layer, 25-45 PGCs/embryo were detected only with stage X-XIV, but not with stage IX blastoderms. However, the culture of dispersed cells from the area pellucida of stages IX-XIII on STO feeder layers yielded about 150 PGCs/embryo. The carbohydrate epitopes recognized by anti-SSEA-1 and EMA-1 first appeared at stage X on cells in association with polyingressing cells on the ventral surface of the epiblast and later on the dorsal surface of the hypoblast. The SSEA-1-positive hypoblast cells gave rise to chicken PGCs when cultured on a feeder layer of quail blastodermal cells. From these observations, we propose that the segregation and development of avian germline is a gradual, epigenetic process associated with the translocation of SSEA-1/EMA-1-positive cells from the ventral surface of the area pellucida at stage X to the dorsal side of the hypoblast at stages XI-XIV.

Soluble factors and the emergence of chick primordial germ cells in vitro

Previous observations obtained from a culture of blastodermal cells on a mouse fibroblast feeder layer (STO) suggested that STO cells provide a factor or factors that facilitate development of avian primordial germ cells (PGC) from dispersed embryo cells. The purpose of the current study was to test the hypothesis that soluble factors produced by STO cells are responsible, at least in part, in supporting the development of PGC in culture and to examine the effect of stem cell factor (SCF), ciliary neurotrophic factor (CNTF), and basic fibroblast growth factor (bFGF) in the development of PGC in culture. Blastodermal cells on gelatin-coated plastic or on feeder layers of CV-1 cells yielded a small number of PGC. When blastodermal cells were cultured on STO cells, a marked increase in PGC was observed. The addition of STO cell-conditioned medium (STO-CM) to blastodermal cells cultured on gelatin-coated plastic and on feeder layers of CV-1 cells resulted in a significant increase in the number of PGC, indicating that soluble factors produced by STO cells can enhance the development of chicken PGC in culture. Supplementation of blastodermal cells with SCF (100 ng/mL) or CNTF (2 ng/mL) or with CNTF and SCF together resulted in a significant increase in the number of PGC after 48 h of culture on feeder layers of CV-1 cells. However, addition of bFGF (100 ng/mL) did not increase PGC. We concluded from these observations that the culture of blastodermal cells on feeder layers of STO and CV-1 cells can be used as a useful biological system in examining the regulatory factors that govern the ontogeny of the germ cell lineage in the avian embryo.

Characterization of stage-specific embryonic antigen-1 (SSEA-1) expression during early development of the turkey embryo

SSEA-1 is a carbohydrate epitope associated with cell adhesion, migration and differentiation. In the present study, SSEA-1 expression was characterized during turkey embryogenesis with an emphasis on its role in primordial germ cell development. During hypoblast formation, SSEA-1 positive cells were identified in the blastocoel and hypoblast and later in the germinal crescent. Based on location and morphology, these cells were identified, as PGCs. Germ cells circulating through embryonic blood vessels were also SSEA-1 positive. During the active phase of migration, PGCs in the dorsal mesentery and gonad could no longer be identified using the SSEA-1 antibody. The presence of PGCs at corresponding stages was verified using periodic acid Schiff stain. Pretreatment of PGCs with trypsin, alpha-galactosidase and neuraminidase did not restore immunoreactivity to SSEA-1. In general, expression was not limited to the germ cell lineage. SSEA-1 was also detected on the ectoderm, yolk sac endoderm, gut and mesonephric tubules. During neural tube closure, SSEA-1 was expressed by the neural epithelium of the fusing neural folds. Later SSEA-1 was detected in regions of the developing spinal cord. Enzyme pretreatment unmasked the epitope on some neural crest cells and cells in the sympathetic ganglion. The temporal and spatial distribution of SSEA-1 in the turkey embryo suggests a role in early germ cell and neural cell development. The absence of SSEA-1 on turkey gonadal germ cells was different from that observed for the chick. Therefore, while features of avian germ cell development appear to be conserved, expression of SSEA-1 can vary with the species.

Sex identification of turkey embryos using a multiplex polymerase chain reaction

A considerable portion of the W chromosome in Gallinaceous birds consists of tandem repetitive DNA. In the turkey, a 0.4-kb PstI element is repeated about 10,000 times in the female diploid genome but is undetectable as such a unit in males. In this study a multiplex polymerase chain reaction was developed to identify the sex of turkeys based upon the PstI repeat. The technique utilized two pairs of primers, the first pair was designed to amplify a region of the PstI repetitive element, resulting in the production of a 177-bp fragment in females. The other pair was designed to amplify a region of the adenosine triphosphate (ATP) synthase gene, present in both males and females. The simultaneous use of all four primers in the same reaction resulted in the coamplification of a 177-bp and a 250-bp fragment in females and a 250-bp fragment in males. This technique was used to verify the sex of 45 adults of known sex and to identify the sex of 74 embryos from Day 5 to hatch. This procedure is rapid and permits the sexing of many embryos in a short time. The ability to sex early embryos can facilitate studies on avian sex determination.

The origin of the avian germ line and transgenesis in birds

The origin of the germ cell lineage in vertebrates is a fundamental question that has preoccupied developmental biologists. Recent work on the origin of the avian germ line has extended and clarified our understanding of the temporal and spatial segregation of primordial germ cells (PGC) during prestreak stages of development. The germ cells first appear at Stage X (Eyal-Giladi and Kochav, 1976) in the ventral surface of the area pellucida in a scattered pattern among polyingressing cells. Subsequently, the PGC gradually translocate from the epiblast to the hypoblast. The entire process appears to be dependent upon the maintenance of an organized area pellucida. Little is known about the regulatory events governing germ cell emergence during this period; however, the culture of dispersed blastodermal cells on a mouse fibroblast feeder layer can compensate for a disorganized area pellucida and offers an in vitro system to examine the molecular basis of germ cell development. Such basic information is valuable for current approaches towards the production of transgenic poultry with targeted changes to the genome through the use of avian embryonic stem cells or primordial germ cells. Refinement of the culture of primordial germ cells or their precursors should allow academic and industrial research laboratories to answer significant biological questions and to improve the genetic potential of commercial poultry stocks. A better understanding of the biology of avian primordial germ cells during early embryo development can only enhance this process.

Egg handling and storage

The temperature and relative humidity of storage, as well as the gaseous environment, interact with the fertile egg over time during storage in such a way as to affect the success of incubation either negatively or positively. This interaction occurs both above and below the "physiological zero", at which embryonic metabolism is minimal. This interaction below physiological zero implies that certain physical aspects of the egg must be affected by the environmental conditions. As the eggshell is a relatively fixed component, changes in albumen, shell membranes, cuticle, yolk, or embryo proper must account for these time- and environment-related effects. It is concluded that the major contributor is the albumen, as it is obviously the most dynamic component below physiological zero and is strategically positioned.

Cloning and characterization of cDNAs encoding two forms of avian stem cell factor

Stem cell factor (SCF), also known as Steel factor, is a transmembrane cytokine involved in several developmental processes and the ligand for the receptor tyrosine kinase c-kit. In several mammalian species, two isoforms of stem cell factor have been reported, a long form in which soluble SCF is released after proteolytic cleavage of the extracellular domain and a short membrane-anchored form in which a region containing a cleavage site is deleted. Currently, only the longer, soluble form has been identified in birds. Therefore, the cDNAs encoding two forms of quail stem cell factor (qSCF) were obtained using RT-PCR with nested primers. The deduced amino acid sequence of the long form of qSCF showed a high degree of homology with chicken (98%) and relatively low homology (approximately 53%) with various mammalian SCFs. Northern blot analysis with the qSCF cDNA revealed the expression of a 5.9 and a 2.7 kb transcript in several quail tissues.

Synergistic action of two sources of avian growth factors on proliferative differentiation of chick embryonic hematopoietic cells

During embryonic development, the components of the avian immune system undergo ontogeny in several distinct organs, including the bone marrow, spleen, thymus, and bursa of Fabricius. This process is regulated and controlled by the complex interactions of various cytokines and colony-stimulating factors (CSF). The objective was to examine the action of two different sources of hematopoietic growth factors, spleen-conditioned media (SCM) and chick embryo extract (CEE), on the proliferation of hematopoietic cells from various organs and on the differentiation of progenitor cells in semi-solid culture. Spleen and bone marrow cells obtained at Day 16 of incubation responded in a dose-dependent manner to the addition of SCM and CEE alone or in combination. No proliferative effect of SCM was observed on cells obtained from embryonic thymus or bursa. Clonal analysis of bone marrow and spleen cells suggested that CEE may contain the avian equivalents of stem cell factor, interleukin-3, granulocyte-macrophage CSF, granulocyte-CSF, and macrophage-CSF. Clonal analysis of SCM cultures suggested that in addition to myelomonocytic growth factor, which affects primarily macrophage-granulocyte lineages, a thrombocyte-CSF-like activity was also apparent. The SCM alone tended to act upon committed late progenitors. The combination of CEE and SCM amplified the size and the total number of colonies obtained and appeared to act synergistically upon progenitors with a high level of proliferative potential. This response on young progenitors was confirmed when cells were cultured in CEE and SCM prior to clonal analysis. These results document the presence of thrombocyte CSF in SCM and the effect of both CEE and SCM on the proliferative differentiation of avian embryonic hematopoietic progenitors.

Profiles of chicken macrophage effector functions

In contrast to the mammalian system, avian species lack the so-called "resident" or "harvestable" macrophage population in the abdominal exudate. However, macrophages can be recruited into the chicken's abdominal cavity (presumably from the blood monocyte pool) if an inflammatory agent such as Sephadex is injected. The kinetics of inflammatory cell recruitment in terms of time, cell type, and state of activation to perform a particular effector function is currently an active area of research. This report will provide information on several chicken macrophage effector functions, including in vivo chemotaxis, phagocytosis, bacterial uptake and killing, biosynthesis of nitric oxide and various enzymes, and monokines such as interleukin-1 and granulocyte colony-stimulating factor.

Use of avian cytokines in mammalian embryonic stem cell culture

Mouse blastocyst-derived embryonic stem (ES) cells are multipotent cells that can be used in vitro as models of differentiation and in vivo can contribute to all embryonic tissues including the germ line. The culture of ES cells requires a source of leukemia inhibitory factor (LIF), often provided by culture with a mouse fibroblast (STO) feeder layer, buffalo rat liver cell-conditioned media (BRL-CM), or the addition of recombinant LIF. To date, all of the ES cell culture systems use mammalian sources of LIF. We found that mouse ES cells can be maintained for over 10 passages in an undifferentiated state with media conditioned by a chicken liver cell line (LMH-CM) or on a feeder layer made with primary chicken embryonic fibroblasts (CEF). These ES cells can undergo both spontaneous and induced differentiation, which is associated with the disappearance or reduction of the expression of alkaline phosphatase and SSEA-1, similar to that observed for ES cells cultured with BRL-CM or STO feeder layers. The ES cells cultured in LMH-CM did not express cytokeratin Endo-A antigen recognized by TROMA-1, but their differentiated progeny did express this antigen. In contrast to LMH-CM, Endo-A was expressed in ES cells cultured on CEF feeder layers and in differentiated progeny. These results indicate that avian cells can produce a LIF-like cytokine that is active in inhibiting the differentiation of mouse ES cells. This could provide a biological end point for the isolation and characterization of avian LIF.

Brain content of cGnRH I and II during embryonic development in chickens

We used specific radioimmunoassays to measure chicken gonadotropin-releasing hormones I and II (cGnRH I and II) in extracts of chicken brain as a first step in determining whether these peptides may function identically during embryonic development in birds. In three experiments chicken embryo brains were removed at various times between Day 6 of incubation and hatching. In Experiment 3, the sex of embryos was identified by means of polymerase chain reaction amplification of a W chromosome-specific DNA sequence. Brain concentrations of cGnRH I increased sharply from Day 6 of incubation to Day 8, then decreased until Day 10 to Day 12, followed by an increase beginning on approximately Day 17 and continuing until hatch. In contrast, cGnRH II concentration remained low until about Day 14 of incubation, then increased progressively until, at hatch, brain content of cGnRH II was approximately 9 to 11 times that of cGnRH I. The difference in development pattern and total content of these peptides supports the view that any physiologic function they may have might be differentiated as early as Day 7 of incubation.

Avian macrophages: contribution to cellular microenvironment and changes in effector functions following activation

The capacity of macrophages to generate metabolites and monokines having effector and regulatory functions can result in a major impact on their cellular microenvironment. Macrophage products synthesized in response to bacterial lipopolysaccharide stimulation include reactive oxygen and nitrogen intermediates as well as tumor necrosis factor (TNF). These secreted products of macrophages exhibit bioactivity either locally or systemically. Although the mechanism of action of avian monokines such as TNF-like factor may be similar to their mammalian counterparts, chicken TNF seems to lyse cells of chicken origin and not of mammalian origin. Furthermore, the generation and activity of products such as TNF is directly influenced by environmental stressors such as heat and toxins.

Early development of the chick embryo

The ultrastructure of the early chick embryo was investigated, using scanning (SEM) and transmission electron microscopy (TEM). Eggs were obtained from the shell gland by injecting hens intravenously with a synthetic prostaglandin or arginine vasopressin. Embryos were examined during late cleavage (stages IV-VI, Eyal-Giladi and Kochav, '76), formation of the area pellucida (stages VII-XI), and formation of the hypoblast (stages X-XIV). SEM highlighted the reduction in cell number at the underside of the embryo during formation of the area pellucida although it became apparent that the thickness of the embryo is not reduced to a single layer of cells at stage X. In addition, blastomeres at the perimeter of embryos (stages V-VI) project filopodial extensions onto a smooth membrane that separates the sub-embryonic cavity from the yolk. During hypoblast formation, epiblast cells generate stellate projections at their basal aspect, thus providing a meshwork for the advancing secondary hypoblast cells. By stage XII the epiblast was one cell thick and reminiscent of a columnar epithelium when viewed transversely. Cells of the deep portion of the posterior marginal zone were distinguished morphologically in the stage XII embryo by their many cell surface projections and ruffled appearance. Blastomeres at the perimeter of stage V-VI embryos projected filopodial extensions onto a smooth membrane which separates the sub-embryonic cavity from the yolk. This membrane is presumed to be confluent with the cytolemma. Evidence is presented demonstrating the presence of intracellular membrane-bound droplets which are hypothesised to contain sub-embryonic fluid.

Efficient transfection of chicken cells by lipofection, and introduction of transfected blastodermal cells into the embryo

Chicken blastodermal cells (CBCs) and primary chicken fibroblasts (PCFs) have been lipofected with a variety of lacZ constructs encoding Escherichia coli beta-galactosidase (beta-gal). A reporter construct (phspPTlacZpA) containing a mouse heat-shock protein 68 gene (hsp 68) promoter was used to establish conditions for efficient lipofection. The construct, in circular or linear plasmid form or as reporter sequences alone, was transferred efficiently by incubating the cells for 3.5 h in a mixture of 6.2 micrograms Lipofectin (a cationic liposome preparation from Bethesda Research Laboratories) and 1.55-3.1 micrograms DNA per mL DMEM. These lipofection conditions were used to transfer a reporter construct (pCBcMtlacZ) containing a Zn(2+)-inducible chicken metallothionein (cMt) promoter, and constructs showing constitutive expression due to Rous sarcoma virus plus chicken beta-actin (pmiwZ) or cytomegalovirus (pMaori3) promoters. Endogenous chicken beta-gal and transferred bacterial beta-gal activity could be distinguished clearly by incubating the cells with the substrate, Xgal, at pH 4.3 or 7.4, respectively. Expression of phspPTlacZpA in chicken cells did not appear to require specific induction of the mouse hsp68 promoter, whereas expression of pCBcMtlacZ required treatment of the cells for 6-12 h with 150 microM ZnCl2. Bacterial beta-gal activity was observed following lipofection of CBCs that were cultured in suspension or plated. The efficiency of lipofection was at least 1 in 25 for CBCs, judging by the proportion of cells shown to have beta-gal activity 16-24 h after lipofection treatment began; these events could represent transient or stable incorporation of the construct.(ABSTRACT TRUNCATED AT 250 WORDS)

Daily infusion of corticosterone and reproductive function in the domestic hen (Gallus domesticus)

The purpose of this study was to examine the effect of the daily infusion of corticosterone on reproductive function in the laying hen and to determine the relationship between the cyclic pattern of plasma concentrations of corticosterone on the open-period for the preovulatory release of LH. An exogenous rhythm of plasma levels of corticosterone was generated using an osmotic pump. Corticosterone was infused subcutaneously into laying hens at rates of 5, 10, 15 or 30 micrograms/hr for a duration of 10 hr beginning with the onset of darkness or at 15 micrograms/hr for 4 hr, or continuously at 30 micrograms/hr. Daily infusions greater than 15 micrograms/hr and the continuous infusion resulted in cessation of ovulation, ovarian and oviductal regression, hyperphagia, and elevated levels of plasma corticosterone compared to that observed in control hens. The hens which were infused with 5 or 10 micrograms/hr of corticosterone maintained normal reproductive function with plasma concentrations of corticosterone that were approximately the same as those in the control hens. The effect of infusing 10 micrograms/hr of corticosterone on the open-period for the preovulatory release of LH was determined under constant light. No significant changes were observed in the frequency distribution of the times of oviposition when hens were infused with 10 micrograms/hr of corticosterone for 12 hr from 9:00 to 21:00 hr or 21:00 to 9:00 hr each day.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of metyrapone on the timing of oviposition and ovarian steroidogenesis in the laying hen

1. The purpose of this study was to observe the effects of metyrapone on the time of oviposition and LH-stimulated steroidogenesis by granulosa cells and small yellow follicles. 2. In experiment 1, White Leghorn hens were injected for 11 d with 240 mg metyrapone 5 h before 'lights off'. Control hens were injected with 1 ml of vehicle (PEG-400). Metyrapone treatment resulted in a 28% decrease in the rate of lay and the modal frequency of the time of oviposition was phase-shifted by 15 h. 3. In experiment 2, hens were injected with 240 mg metyrapone 5 h before 'lights off' or at 'lights on'. While metyrapone treatment reduced the rate of lay, a clear phase-shift in the distribution of oviposition was not observed. Basal and LH-stimulated progesterone synthesis by the granulosa cells of the largest follicle and oestradiol synthesis by small yellow follicles was significantly reduced. 4. Metyrapone treatment significantly reduced basal, but not LH-stimulated output of androstenedione by whole small yellow follicles compared to that observed in control hens. 5. The addition of metyrapone in vitro to isolated granulosa cells from the three largest preovulatory follicles inhibited LH-stimulated progesterone production in a dose-specific manner. 6. The results of this study suggest that the ability of metyrapone to perturb the open-period is a pharmacological effect mediated through inhibition of ovarian and adrenal steroidogenesis.

Variability in preincubation embryo development in domestic fowl. 1. Effects of nest holding time and method of egg storage

Embryos of eggs from Single Comb White Leghorn hens were analyzed to determine whether nest holding time and method of storage had a significant effect on postoviposition embryonic growth prior to incubation. Eggs were collected from 38- to 42-wk-old hens naturally inseminated and housed in floor pens. The experiment had a 2 x 2 factorial arrangement of treatments with two nest holding times and two storage methods. Eggs were collected within 1 h of oviposition, placed on cardboard egg flats, and stored unpacked (Treatment 1), or put on flats, and packed in 30-dozen egg cases (Treatment 2). Eggs in Treatments 3 and 4 were marked within 1 h of oviposition, but remained in the nest for 6 to 7 h. These eggs were separated into unpacked (Treatment 3), and packed (Treatment 4) groups. All eggs were stored at 13.8 C for 4 days. A total of 250 embryos were staged after storage for development using the Eyal-Giladi and Kochav classification. Least square means (LSM) for stage of development were: Treatment 1, 10.76; Treatment 2, 11.52; Treatment 3, 12.41; and Treatment 4, 12.36. For the main effects, nest holding time significantly affected stage of development (P = .0001), but storage method (P = .1140) and nest holding time by storage method interaction (P = .0730) did not. Comparison of LSM of Treatment 1 versus 3 (P = .0001), 2 versus 4 (P = .0152), and 1 versus 2 (P = .0214) were significant, but Treatment 3 versus 4 (P = .8595) was not.(ABSTRACT TRUNCATED AT 250 WORDS)

Assessment of functional gametes in chickens after transfer of primordial germ cells

The ability of primordial germ cells (PGCs) transferred from donor to recipient embryos to form functional gametes was assessed using feather colour as a phenotypic marker. Donor primordial germ cells were obtained in blood samples taken from Dwarf White Leghorn embryos, homozygous for the dominant allele at the locus for 'dominant white' plumage (I), which had been incubated for 52 h. Blood samples containing PGCs were transferred by intravascular injection to Barred Plymouth Rock embryos (ii) incubated for 53, 72 and 96 h. Of the embryos which hatched, 28 were male and 31 were female. All chicks were raised to sexual maturity and test mated with Barred Plymouth Rock fowl. All of the 3117 offspring exhibited the typical Barred Plymouth Rock phenotype; no Barred Plymouth Rock x Dwarf White Leghorn chicks were obtained. The results of this study suggest that the frequency of transmission of the donor line genotype after PGC transfer must be improved for this technique to be useful for the routine development of transgenic poultry.

Production of somatic and germline chimeras in the chicken by transfer of early blastodermal cells

Cells were isolated from stage X embryos of a line of Barred Plymouth Rock chickens (that have black pigment in their feathers due to the recessive allele at the I locus) and injected into the subgerminal cavity of embryos from an inbred line of Dwarf White Leghorns (that have white feathers due to the dominant allele at the I locus). Of 53 Dwarf White Leghorn embryos that were injected with Barred Plymouth Rock blastodermal cells, 6 (11.3%) were phenotypically chimeric with respect to feather colour and one (a male) survived to hatching. The distribution of black feathers in the recipients was variable and not limited to a particular region although, in all but one case, the donor cell lineage was evident in the head. The male somatic chimera was mated to several Barred Plymouth Rock hens to determine the extent to which donor cells had been incorporated into his testes. Of 719 chicks hatched from these matings, 2 were phenotypically Barred Plymouth Rocks demonstrating that cells capable of incorporation into the germline had been transferred. Fingerprints of the blood and sperm DNA from the germline chimera indicated that both of these tissues were different from those of the inbred line of Dwarf White Leghorns. Bands that were present in fingerprints of blood DNA from the chimera and not present in those of the Dwarf White Leghorns were observed in those of the Barred Plymouth Rocks.(ABSTRACT TRUNCATED AT 250 WORDS)

Reptilian and avian follicular hierarchies: models for the study of ovarian development

The presence of an ovarian follicular hierarchy is a characteristic feature of reptiles and birds. The hierarchy contains follicles at all stages of maturation and therefore, varying degrees of sensitivity to the ovulation-inducing effects of the gonadotropins. In the hen, ovulability is gained as the ability of the follicle to produce androgens and estrogens declines and the ability to produce progesterone increases. In the mature follicle, the granulosa cells are the site of progesterone production whereas the theca cells produce androgens and estrogens. Small follicles that have not yet been (and may never be) recruited into the yolk-filled hierarchy are the major producers of androgens and estrogens within the ovary. In reptiles the ovarian follicular hierarchy includes non-vitellogenic follicles and in some species includes follicles destined to become atretic. These two features distinguish the reptiles from the birds and provide experimental biologists with a unique model to investigate the physiological events that regulate the most common fate of ovarian follicles, atresia.

The effect of corticosterone on the response of the ovary to pregnant mare's serum gonadotrophin in sexually immature pullets

Several studies have suggested that a functional relationship exists between the adrenal gland and the ovary. The purpose of this study was to determine the effect of corticosterone on the sensitivity of the ovary to exogenous gonadotrophin. Sexually immature White Leghorn pullets, 18 weeks of age, were infused with 30 micrograms/hr of corticosterone for 14 days. After 7 days of infusion, the pullets were injected with 3, 15, 75, or 375 IU pregnant mare's serum gonadotrophin (PMSG) for 7 days. Controls consisted of noninfused pullets injected according to the same doses of PMSG. Blood samples were obtained on Days 3, 6, 8, 10, and 12 of infusion and were assayed for plasma concentrations of luteinizing hormone (LH), estradiol, and corticosterone by radioimmunoassay. The daily injections of 75 or 375 IU PMSG in noninfused pullets resulted in an increase in ovarian and oviductal weight and the formation of a hierarchy of yolk-filled follicles. This was accompanied by an increase in the plasma concentrations of estradiol and a decrease in the plasma concentrations of LH. The infusion of corticosterone significantly increased the plasma concentrations of this steroid over that observed in the control pullets and was not related to the dose of PMSG. This increase in plasma levels of corticosterone was associated with a significant decline in the plasma concentrations of LH and estradiol before the injection of PMSG. After 6 days of PMSG treatment, the plasma concentrations of estradiol increased to that observed in control pullets and was dependent upon the dose of PMSG injected.(ABSTRACT TRUNCATED AT 250 WORDS)

The effect of corticosterone on the photoperiodic response of immature hens

White Leghorn pullets, 18 weeks of age, were infused with 30 micrograms/hr of corticosterone for 14 days. After 7 days of continuous infusion, the pullets were photostimulated by transfer from 8L:16D to 16L:8D. Noninfused controls were either photostimulated on Day 7 or remained on an 8L:16D photoschedule. Blood samples were obtained on 3, 6, 8, 10, and 12 days of infusion and were assayed for plasma concentrations of LH, estradiol, and corticosterone by radioimmunoassay. On Day 14 all birds were weighed and sacrificed, and the ovarian and oviductal weights were recorded. Photostimulation had no effect on plasma concentrations of corticosterone. The infusion of corticosterone significantly raised the plasma concentration to 5.2 ng/ml, suppressed the photo-induced rise in plasma concentrations of LH, and resulted in significantly lower plasma concentrations of estradiol. After 7 days of photostimulation either with or without corticosterone infusion, there were no significant differences in mean ovarian weight. The oviducal weight of hens infused with corticosterone was, however, significantly lowered. It is suggested that one of the mechanisms associated with the antigonadal effect of corticosterone involves an inhibition of Gn-RH release by the hypothalamus.

Interrelationships between the hypothalamus, pituitary gland, ovary, adrenal gland, and the open period for LH release in the hen (Gallus domesticus)

The asynchronous ovulatory cycle of the hen is believed to be the consequence of two interacting systems, one of which is circadian and regulates the timing of the preovulatory LH surge. In support of this proposition, the open period for LH release was shown to oscillate with the same periodicity as the photoschedule when the hens were exposed to 14 L:7 D, 14 L:10 D, and 14 L:14 D. In addition, it was demonstrated that follicular maturation is not affected by or synchronized with the photoperiod. The physiological system that transduces the light/dark cycle into an open period for LH release has not been identified although circumstantial evidence supports the idea that the adrenal gland plays a role in this function. This evidence includes the anatomical juxtaposition of the left ovary and adrenal gland, innervation of steroid-producing cells within the follicle by nerve tracts passing through the adrenal glands, the ability of injections of metyrapone to alter the timing of preovulatory LH release, the ability of injections of corticosterone to induce ovulation when a mature follicle is present in the ovary, and the ability of dexamethasone or infusions of corticosterone to block ovulation. Recently we have also shown that infusions of corticosterone will block the gonadotropic effect of PMSG, will inhibit the photoperiodic response, and do not affect the release of LH in response to injections of GnRH. The addition of corticosterone to incubations of dispersed granulosa cells does not affect their response to LH. These data suggest that corticosterone may modulate the responsiveness of the hypothalamus to tropic stimuli and demonstrate that exposure to corticosterone can alter the responsiveness of some ovarian tissues to gonadotropins.

The influence of cage versus floor pen management of broiler breeder hens on subsequent performance of cage reared broilers

Chicks from breeder hens maintained in cages or floor pens were reared in Lohman battery cages in three separate trials. The ages of the breeder flock at the time of egg collection were 29, 36, and 54 weeks, respectively. The fertility of the artificially inseminated caged hens was significantly (P less than .05) lower than that of the naturally mated hens. The source of hatching eggs had no effect on early embryonic mortality, feed conversion, or growing period mortality in any broiler trials. Hatchability of all eggs set was significantly (P less than .05) lower for caged breeders in Trials 2 and 3. In all trials, eggs from caged hens produced significantly (P less than .05) larger day-old chicks than their floor-housed counterparts; however, these chicks were significantly (P less than .05) heavier at slaughter only in Trial 2. Carcass evaluations for breast blisters, keel malformations, and leg abnormalities revealed that the severity of each condition was associated with the sex of the broiler and that, within sexes, maternal housing management had no effect.

The influence of flock uniformity on the reproductive performance of broiler breeder hens housed in cages and floor pens

Two flocks of broiler breeder hens, differing in uniformity of body weight, were evaluated under cage and floor management systems over a 28-week period. Hens were housed singly in cages (N = 280) or in litter floor pens (N = 304). Caged hens were artificially inseminated with .05 ml of pooled semen once weekly. Floor birds were mated naturally. During the first 10 weeks of production, the more uniform flock exhibited significantly higher egg production than the less uniform flock. Uniformity did not influence cumulative egg production, egg weight, fertility, or mortality. Initial egg production was similar for caged and floor housed hens, but the caged birds attained significantly higher egg production during peak production. Caged females showed higher egg weights and body weights than did the floor females throughout the study. Naturally mated birds attained significantly higher fertility than artificially inseminated birds (94.9 vs. 90.6). Correlation coefficients for the weights of caged hens at 20 and 24 weeks with 24, 32, 40, and 50 week weights, total eggs per bird, and age at first egg indicated that body weight at 24 weeks was a better indicator of subsequent flock performance than was body weight at 20 weeks.