Igal Y. Pevzner

Differential cytokine mRNA expression in heterophils isolated from Salmonella-resistant and -susceptible chickens

We recently showed that increased in vitro heterophil functional efficiency translates to increased in vivo resistance to a systemic Salmonella enteritidis (SE) infection utilizing a parental pair of broiler chickens (lines A and B) and the F1 reciprocal crosses (C and D). Heterophils produce cytokines and modulate acute protection against Salmonella in young poultry. Therefore, we hypothesize that heterophils from SE‐resistant chickens (A and D) have the ability to produce an up‐regulated pro‐inflammatory cytokine response compared to that of heterophils from SE‐susceptible chickens (B and C). In this study, heterophils were isolated from day‐old chickens and treated with either RPMI‐1640 (as the control), or phagocytic agonists (SE, or SE opsonized with either normal chicken serum or immune serum against SE) and cytokine mRNA expression assessed using real‐time quantitative reverse transcription–polymerase chain reaction. Heterophils from SE‐resistant chickens (A and D) had significantly higher levels of pro‐inflammatory cytokine (interleukin (IL)‐6, IL‐8, and IL‐18) mRNA expression upon treatment with all agonists compared to heterophils from SE‐susceptible lines (B and C). Further, heterophils from SE‐resistant chickens had significantly decreased mRNA expression levels of transforming growth factor‐β4, an anti‐inflammatory cytokine, when compared to heterophils from SE‐susceptible chickens. These data indicate cytokine gene expression in heterophils may be a useful parameter in determining resistance to Salmonella, as indicated by our previous in vivo SE studies. Therefore, heterophil functional efficiency and cytokine production may be useful biomarkers for poultry breeders to consider when developing new immunocompetent lines of birds.

Heterophils isolated from chickens resistant to extra-intestinal Salmonella enteritidis infection express higher levels of pro-inflammatory cytokine mRNA following infection than heterophils from susceptible chickens

Previous studies showed differences in in vitro heterophil function between parental (A > B) broilers and F1 reciprocal crosses (D > C). Our objectives were to (1) determine if in vitro variations translate to differences in resistance to Salmonella enteritidis (SE) and (2) quantitate cytokine mRNA in heterophils from SE-infected chicks. One-day-old chicks were challenged and organs were cultured for SE. Chicks with efficient heterophils (A and D) were less susceptible to SE compared to chicks with inefficient heterophils (B and C). Heterophils were isolated from SE-infected chicks and cytokine mRNA expression was evaluated using quantitative real-time RT-PCR. Pro-inflammatory cytokine mRNA was up-regulated in heterophils from SE-resistant chicks compared to susceptible chicks. This is the first report to quantitate cytokine mRNA in heterophils from SE-infected chicks. These data show a relationship between in vitro heterophil function, increased pro-inflammatory cytokine mRNA expression, and increased resistance to SE in 1-day-old chicks.

Functional comparison of heterophils isolated from commercial broiler chickens

Heterophils from two pure lines (A and B) of commercial broiler chickens were isolated on days 1, 4, and 7 post-hatch to evaluate their ability to (1) phagocytose Salmonella enteritidis (SE) (2) degranulate when exposed to immune-IgG opsonized SE, and (3) produce an oxidative burst. On days 1 and 4, heterophils from line A were functionally more efficient compared to heterophils from line B (p<0.05). By 7 days post hatch, heterophil functions for both lines were comparable. To further study the inheritance of heterophil functional efficiency, F1 reciprocal crosses (line C=male B×female A; line D=male A×female B) were evaluated for functional activity and compared with the immunologically efficient (A) and non-efficient (B) parent lines. Heterophils from line D had a more efficient heterophil function (p<0.05) when compared to heterophils from C. These results suggest that heterophil function and efficiency can be genetically transferred to progeny. Moreover they indicate that heterophil function is sex-associated and genetically controlled by the rooster since progeny of line A males maintained immunologically efficient characteristics whereas heterophils from the progeny of line B roosters remained immunologically inefficient. To our knowledge, this is the first report to describe a functional relationship between pure and F1 reciprocal crosses of broiler chickens with regard to heterophils and the innate immune response.

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

Evidence is presented for a crossover between the genes coding for the serologically determined (SD) antigens on erythrocytes and an immune response gene (Ir-GAT) controlling immune response to the synthetic polypeptide GAT within theB complex, the MHC of chickens. TheIr-GAT1 andIr-GAT19 alleles control low and high immune response to GAT, respectively. Both low and high responders were recovered as recombinants fromB1B1 andB19B19 birds. The low-responder haplotypes are homozygous for theIr-GAT1 allele and the high-responder haplotypes carry theIr-GAT19 allele. Mortality forB1B1 nonresponder birds was 39%, compared with 19% for theB1B1 high responders; this suggests the possibility that genes located within the immune response region of theB complex exert some genetic control over viability and survival.

Differential mRNA expression of the avian-specific toll-like receptor 15 between heterophils from Salmonella-susceptible and -resistant chickens

Pattern recognition receptors (PRRs) are essential for recognition of conserved molecular constituents found on infectious microbes. Toll-like receptors (TLRs) are a critical component of the PRR repertoire and are coupled to downstream production of cytokines, chemokines, and antimicrobial peptides by TLR adaptor proteins. Our laboratory previously demonstrated a role for TLR function in the differential innate response of two lines of chickens to bacterial infections. The aim of the present study was to elucidate the role of TLRs in the differential innate responsiveness by measuring differences between lines A (resistant) and B (susceptible) in heterophil mRNA expression of selected TLRs (TLRs 4, 5, and 15) and TLR adaptor proteins (MyD88, TRIF, and TIRAP) in response to stimulation with Salmonella enterica serovar Enteritidis (SE). Although heterophils from both lines had significantly increased expression of TLR 15 mRNA in response to stimulation with SE, heterophils from chickens resistant to infection with SE had significantly greater levels of TLR 15 mRNA expression prior to and following stimulation with SE than heterophils from chickens susceptible to infection with SE. No significant differences were noted between lines in nonstimulated levels of TIRAP, but upon SE stimulation, line A birds had higher levels of expression than B birds. No significant differences were found in heterophils between lines for mRNA expression of TLRs 4 and 5 nor MyD88 and TRIF. These data indicate that differences in the gene expression of TLR 15 by heterophils likely accounts for some of the observed differences between the lines in their susceptibility to infection.

Profiling pro-inflammatory cytokine and chemokine mRNA expression levels as a novel method for selection of increased innate immune responsiveness

Previous studies using F1 reciprocal crosses and two parental lines of broilers show the sire is instrumental in determining the in vitro leukocyte function and cytokine/chemokine profile. Since the innate immune response is the primary means young chickens have to protect themselves, we hypothesize utilizing a novel genomics approach to select sires based on an elevated pro-inflammatory cytokine and chemokine profile. By identifying sires with increased pro-inflammatory cytokine (interleukin [IL]-1beta and IL-6) and chemokine (CXCLi2 and CCLi2) mRNA expression levels, we expect the progeny will also have elevated profiles. We characterized the pro-inflammatory cytokine and chemokine profile of 119 sires using quantitative real-time RT-PCR (qRT-PCR) and identified two populations with inherently high and low mRNA expression levels of IL-1beta, IL-6, CXCLi2, and CCLi2. Select high and low sires were then used to produce progeny for the second phase of the trial. Blood samples were collected from 214 progeny and the cytokine and chemokine mRNA expression levels determined. Progeny from high sires had significantly (P<or=0.02) higher cytokine (IL-1beta and IL-6) and chemokine (CXCLi2 and CCLi2) mRNA expression levels compared to progeny from low sires. We have identified a broiler population of sires with higher and lower than average pro-inflammatory cytokine/chemokine mRNA expression levels and used them to produce progeny with similar profiles.

Selection of Broilers with Improved Innate Immune Responsiveness to Reduce On-Farm Infection by Foodborne Pathogens

Economic pressure on the modern poultry industry has directed the selection process towards fast-growing broilers that have a reduced feed conversion ratio. Selection based heavily on growth characteristics could adversely affect immune competence leaving chickens more susceptible to disease. Since the innate immune response directs the acquired immune response, efforts to select poultry with an efficient innate immune response would be beneficial. Our laboratories have been evaluating the innate immune system of two parental broiler lines to assess their capacity to protect against multiple infections. We have shown increased in vitro heterophil function corresponds with increased in vivo resistance to Gram-positive and Gram-negative bacterial infections. Additionally, there are increased mRNA expression levels of pro-inflammatory cytokines/chemokines in heterophils isolated from resistant lines compared to susceptible lines. Collectively, all data indicate there are measurable differences in innate responsiveness under genetic control. Recently, a small-scale selection trial was begun. We identified sires within a broiler population with higher and/or lower-than-average pro-inflammatory cytokine/chemokine mRNA expression levels and subsequently utilized small numbers of high-expressing and low-expressing sires to produce progeny with increased or decreased, respectively, pro-inflammatory cytokine/chemokine profiles. This novel approach should allow us to improve breeding stock by improving the overall immunological responsiveness. This will produce a line of chickens with an effective pro-inflammatory innate immune response that should improve resistance against diverse pathogens, improve responses to vaccines, and increase livability. Ongoing work from this project is providing fundamental information for the development of poultry lines that will be inherently resistant to colonization by pathogenic and food-poisoning microorganisms. Utilization of pathogen-resistant birds by the poultry production industry would significantly enhance the microbiological safety of poultry products reaching the consumer.

The Paternal Effect of Campylobacter jejuni Colonization in Ceca in Broilers

Campylobacter jejuni is one of the most common causes of acute enteritis worldwide. Chickens are believed to be the main reservoir of C. jejuni. The role that host genetics play in resistance/susceptibility to C. jejuni colonization in broilers is still not clear. Day-old broilers from 2 parental lines (A and B) and their F(1) reciprocal crosses (C and D) were challenged orally with 10(5) cfu of C. jejuni to address the role of genetics in determining resistance/susceptibility to C. jejuni colonization in broilers. Cloacal swabs were collected on 6, 10, and 13 d postinoculation (dpi), and cecal contents cultured for C. jejuni on 7 and 14 dpi. The number of C. jejuni colonies in the cloacal swabs and cecal contents of each bird were recorded at each time point. Significantly fewer bacteria were found in the cecal contents from line A than B (P < 0.05) and cross D (A male x B female) when compared with cross C (A female x B male) at both 7 and 14 dpi. There was a significant correlation between C. jejuni counts in cloacal swabs and those in cecal contents. The results indicated that a paternal effect might be one of the important genetic factors influencing resistance to C. jejuni colonization in broilers.

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

Recent studies suggest that the gene locus controlling the fate of tumors induced by Rous sarcoma virus (RSV) is linked to theB histocompatibility complex. Birds carrying the dominant allele regress the tumor; homozygous recessives being unable to do so, develop large tumors and die. These are called progressors.The Bryan strain of RSV was inoculated into 220 6 week old Leghorns homozygous forB1B1,B2B2, orB19B19 of which the percentages of progressors were 79, 22 and 56, respectively. The balance of each were regressors and survived.TheB1B1 test birds were derived from special matings, i.e., high and low immune responders to the amino acid polymer, GAT. Of 67 tests progeny of theB1B1 GAT-low mating, 63 or 94% proved to be progressors, and 6% were regressors. Of 84 test progeny of theB1B1 GAT-high matings, 67% were progressors, and 33% were regressors. The difference between the high and low GAT responders is highly significant and indicates that the locus controlling the fate of RSV-induced tumors is closely linked to the locus controlling immune response to GAT. The latter maps within theIr region of theB histocompatibility complex.

Association between in vitro heterophil function and the feathering gene in commercial broiler chickens.

We recently showed that in vitro heterophil functional efficiency in commercial broiler chickens is genetically controlled and may be a sex-associated trait. To further characterize the genetic mechanism(s) of heterophil functional efficiency, we wanted to determine whether the feathering gene, present on the Z sex chromosome, contributes to heterophil functional efficiency. Heterophils from two pairs of broiler lines were evaluated; eachpair contained a fast feather (FF) (lines A and X) and a slow feather (SF) line (lines B and Y). On days 1 and 4 post-hatch, heterophils isolated from two sets of pure line broilers (A and B, and X and Y) were evaluated for their ability to (1) phagocytize Salmonella enteritidis, and (2) exhibit bactericidal activity against S. enteritidis. On days 1 and 4 post-hatch, heterophils isolated from the FF lines were statistically (P < 0.02) more proficient at phagocytizing S. enteritidis than heterophils from SF lines. Bactericidal activity was also statistically (p ≤ 0.02) greater on day 1 post-hatch in the heterophils isolated from FF lines compared to heterophils isolated from SF lines. These data indicate that the presence of the FF gene locus on the Z sex chromosome contributes to heterophil function and may contribute to the early innate immune competence of a flock.