Creating Disease Resistant Chickens: A Viable Solution to Avian Influenza?

Influenza A virus (IAV) represents an ongoing threat to human and animal health worldwide. The generation of IAV-resistant chickens through genetic modification and/or selective breeding may help prevent viral spread. The feasibility of creating genetically modified birds has already been demonstrated with the insertion of transgenes that target IAV into the genomes of chickens. This approach has been met with some success in minimising the spread of IAV but has limitations in terms of its ability to prevent the emergence of disease. An alternate approach is the use of genetic engineering to improve host resistance by targeting the antiviral immune responses of poultry to IAV. Harnessing such resistance mechanisms in a "genetic restoration" approach may hold the greatest promise yet for generating disease resistant chickens. Continuing to identify genes associated with natural resistance in poultry provides the opportunity to identify new targets for genetic modification and/or selective breeding. However, as with any new technology, economic, societal, and legislative barriers will need to be overcome before we are likely to see commercialisation of genetically modified birds.

Gonadal and Endocrine Analysis of a Gynandromorphic Chicken.

Birds have a ZZ male and ZW female sex chromosome system. The relative roles of genetics and hormones in regulating avian sexual development have been revealed by studies on gynandromorphs. Gynandromorphs are rare bilateral sex chimeras, male on one side of the body and female on the other. We examined a naturally occurring gynandromorphic chicken that was externally male on the right side of the body and female on the left. The bird was diploid but with a mix of ZZ and ZW cells that correlated with the asymmetric sexual phenotype. The male side was 96% ZZ, and the female side was 77% ZZ and 23% ZW. The gonads of this bird at sexual maturity were largely testicular. The right gonad was a testis, with SOX9+ Sertoli cells, DMRT1+ germ cells, and active spermatogenesis. The left gonad was primarily testicular, but with some peripheral aromatase-expressing follicles. The bird had low levels of serum estradiol and high levels of testosterone, as expected for a male. Despite the low percentage of ZW cells on that side, the left side had female sex-linked feathering, smaller muscle mass, smaller leg and spur, and smaller wattle than the male side. This indicates that these sexually dimorphic structures must be at least partly independent of sex steroid effects. Even a small percentage of ZW cells appears sufficient to support female sexual differentiation. Given the lack of chromosome-wide dosage compensation in birds, various sexually dimorphic features may arise due to Z-gene dosage differences between the sexes.

Characterization of zebrafish polymerase III promoters for the expression of short-hairpin RNA interference molecules.

RNA interference (RNAi) is a powerful, sequence specific, and long-lasting method of gene knockdown, and can be elicited by the expression of short-hairpin RNA (shRNA) molecules driven via polymerase III type 3 promoters from a DNA vector or transgene. To further develop RNAi as a tool in zebrafish, we have characterized the zebrafish U6 and H1 snRNA promoters and compared the efficiency of each of the promoters to express an shRNA and silence a reporter gene, relative to previously characterized U6 promoters from pufferfish, chicken, and mouse. Our results show that the zebrafish polymerase III promoters were capable of effective gene silencing in the zebrafish ZF4 cell line, but were ineffective in mammalian Vero cells. In contrast, mouse and chicken promoters were active in Vero but not ZF4 cells, highlighting the importance of homologous promoters to achieve effective silencing.

The potential role of microRNAs in regulating gonadal sex differentiation in the chicken embryo.

Differential gene expression regulates tissue morphogenesis. The embryonic gonad is a good example, where the developmental decision to become an ovary or testis is governed by female- or male-specific gene expression. A number of genes have now been identified that control gonadal sex differentiation. However, the potential role of microRNAs (miRNAs) in ovarian and testicular pathways is unknown. In this review, we summarise our current understanding of gonadal differentiation and the possible involvement of miRNAs, using the chicken embryo as a model system. Chickens and other birds have a ZZ/ZW sex chromosome system, in which the female, ZW, is the heterogametic sex, and the male, ZZ, is homogametic (opposite to mammals). The Z-linked DMRT1 gene is thought to direct testis differentiation during embryonic life via a dosage-based mechanism. The conserved SOX9 gene is also likely to play a key role in testis formation. No master ovary determinant has yet been defined, but the autosomal FOXL2 and Aromatase genes are considered central. No miRNAs have been definitively shown to play a role in embryonic gonadal development in chickens or any other vertebrate species. Using next generation sequencing, we carried out an expression-based screen for miRNAs expressed in embryonic chicken gonads at the time of sexual differentiation. A number of miRNAs were identified, including several that showed sexually dimorphic expression. We validated a subset of miRNAs by qRT-PCR, and prediction algorithms were used to identify potential targets. We discuss the possible roles for these miRNAs in gonadal development and how these roles might be tested in the avian model.

Inhibition of Henipavirus infection by RNA interference.

Nipah virus (NiV) and Hendra virus (HeV) are recently emerged zoonotic paramyxoviruses exclusively grouped within a new genus, Henipavirus. These viruses cause fatal disease in a wide range of species, including humans. Both NiV and HeV have continued to re-emerge sporadically in Bangladesh and Australia, respectively. There are currently no therapeutics or vaccines available to treat Henipavirus infection and both are classified as BSL4 pathogens. RNA interference (RNAi) is a process by which double-stranded RNA directs sequence-specific degradation of messenger RNA in animal and plant cells. Small interfering RNAs (siRNAs) mediate RNAi by inhibiting gene expression of homologous mRNA and our preliminary studies suggest RNAi may be a useful approach to developing novel therapies for these highly lethal pathogens. Eight NiV siRNA molecules (four L and four N gene specific), two HeV N gene specific, and two non-specific control siRNA molecules were designed and tested for their ability to inhibit a henipavirus minigenome replication system (which does not require the use of live virus) in addition to live virus infections in vitro. In the minigenome assay three out of the four siRNAs that targeted the L gene of NiV effectively inhibited replication. In contrast, only NiV N gene siRNAs were effective in reducing live NiV replication, suggesting inhibition of early, abundantly expressed gene transcripts may be more effective than later, less abundant transcripts. Additionally, some of the siRNAs effective against NiV infection were only partially effective inhibitors of HeV infection. An inverse correlation between the number of nucleotide mismatches and the efficacy of siRNA inhibition was observed. The demonstration that RNAi effectively inhibits henipavirus replication in vitro, is a novel approach and may provide an effective therapy for these highly lethal, zoonotic pathogens.

Characterization and comparison of chicken U6 promoters for the expression of short hairpin RNAs.

RNA interference (RNAi) is a powerful method of sequence-specific gene knockdown that can be mediated by DNA-based expression of short hairpin RNA (shRNA) molecules. A number of vectors for expression of shRNA have been developed with promoters for a small group of RNA polymerase III (pol III) transcripts of either mouse or human origin. To advance the use of RNAi as a tool for functional genomic research and future development of specific therapeutics in the chicken species, we have developed shRNA expression vectors featuring chicken U6 small nuclear RNA (snRNA) promoters. These sequences were identified based on the presence of promoter element sequence motifs upstream of matching snRNA sequences that are characteristic of these types of pol III promoters. To develop suitable shRNA expression vectors specifically for chicken functional genomic RNAi applications, we compared the efficiency of each of these promoters to express shRNA molecules. Promoter activity was measured in the context of RNAi by targeting and silencing the reporter gene encoding the enhanced green fluorescent protein (EGFP). Plasmids containing one of four identified chicken U6 promoters gave a similar degree of knockdown in DF-1 cells (chicken); although, there was some variability in Vero cells (monkey). Because the chicken promoters were not stronger than the benchmark mouse U6 promoter, we suggest that the promoter sequence and structure is more important in determining efficiency in vitro rather than its species origin.

Immune responses to dsRNA: implications for gene silencing technologies.

Nucleic acid-induced gene silencing, such as RNA interference (RNAi), induces a multitude of responses in addition to the knockdown of a gene. This is best understood in the context of the antiviral immune response, from which the processes of RNAi are thought to be derived. Viral challenge of a vertebrate host leads to an intricate series of responses that orchestrate antiviral immunity. The success of this multifaceted system in overcoming viral encounters hinges on complex pathogen-host interactions. One aspect of these interactions, the nucleic acid-based immune response, is key to the successful resolution of a viral challenge. In particular, dsRNA, a nucleic acid associated with viral replication, is involved in numerous interactions contributing to induction, activation and regulation of antiviral mechanisms. Specifically, dsRNA is responsible for stimulating important protective responses, such as the activation of dicer-related antiviral pathways, induction of type 1 IFN, and stimulation of dsRNA-activated protein kinase and oligoadenylate synthetase. Furthermore, the modulation and shaping of this overall immune response is facilitated through nucleic acid interactions with pattern recognition receptors such as toll-like receptor 3. These diverse dsRNA-induced antiviral responses have implications for biotechnologies that use dsRNA to harness one arm of the host antiviral machinery for silencing a specific target gene. The interlinked nature of these response elements means that it may be difficult to completely isolate one element from the other arms of the antiviral response program of an organism. Thus, it is beneficial to understand all aspects of the immune response to dsRNA in order to manipulate these systems and minimize unwanted non-specific effects.