Association of a chicken repetitive element with the endogenous virus-21 slow-feathering locus

Endogenous viral gene ev21 is not responsible for the expression of late feathering in chickens

The late-feathering (LF) gene K on the Z chromosome is an important gene in the chicken industry, which is frequently utilized for the feather sexing, a type of autosexing, of neonatal chicks. The K gene is closely associated with the endogenous ev21 gene from an avian leukosis virus and the incomplete duplication (ID) of prolactin receptor (PRLR) and sperm flagellar protein 2 (SPEF2) genes, and ev21 has been used as a molecular marker to detect LF birds. In the present study, a comprehensive survey for the presence or absence of ev21 and ID across 1,994 birds from 52 chicken breeds, three commercial hybrid groups, and the Red Jungle Fowl revealed that almost all LF breeds have both ev21 and ID. However, only one LF breed (Ingie) has only ID and no ev21. Moreover, this study revealed that almost all early (normal)-feathering (EF) breeds lack both ev21 and ID, but only one breed (White Plymouth Rock) included EF birds with ev21 but no ID. Therefore, regarding LF expression, the results indicated that ID is responsible, but ev21 is not required. Henceforth, ID should be used as a molecular marker to detect LF birds instead of ev21. Because ev21 contains the full genome of an avian leukosis virus, there is a risk of disease development in breeds with this gene. Therefore, the Ingie breed, which has no ev21 at the K locus, represents excellent material for the establishment of new LF stocks.

Characterization of microRNA and mRNA expression profiles in skin tissue between early-feathering and late-feathering chickens

Background

Early feathering and late feathering in chickens are sex-linked phenotypes, which have commercial application in the poultry industry for sexing chicks at hatch and have important impacts on performance traits. However, the genetic mechanism controlling feather development and feathering patterns is unclear. Here, miRNA and mRNA expression profiles in chicken wing skin tissues were analysed through high-throughput transcriptomic sequencing, aiming to understand the biological process of follicle development and the formation of different feathering phenotypes.

Results

Compared to the N1 group with no primary feathers extending out, 2893 genes and 31 miRNAs displayed significantly different expression in the F1 group with primary feathers longer than primary-covert feathers, and 1802 genes and 11 miRNAs in the L2 group displayed primary feathers shorter than primary-covert feathers. Only 201 altered genes and 3 altered miRNAs were identified between the N1 and L2 groups (fold change > 2, q value < 0.01). Both sequencing and qPCR tests revealed that PRLR was significantly decreased in the F1 and L2 groups compared to the N1 group, whereas SPEF2 was significantly decreased in the F1 group compared to the N1 or L2 group. Functional analysis revealed that the altered genes or targets of altered miRNAs were involved in multiple biological processes and pathways related to feather growth and development, such as the Wnt signalling pathway, the TGF-beta signalling pathway, the MAPK signalling pathway, epithelial cell differentiation, and limb development. Integrated analysis of miRNA and mRNA showed that 14 pairs of miRNA-mRNA negatively interacted in the process of feather formation.

Conclusions

Transcriptomic sequencing of wing skin tissues revealed large changes in F1 vs. N1 and L2 vs. N1, but few changes in F1 vs. L2 for both miRNA and mRNA expression. PRLR might only contribute to follicle development, while SPEF2 was highly related to the growth rate of primary feathers or primary-covert feathers and could be responsible for early and late feather formation. Interactions between miR-1574-5p/NR2F, miR-365-5p/JAK3 and miR-365-5p/CDK6 played important roles in hair or feather formation. In all, our results provide novel evidence to understand the molecular regulation of follicle development and feathering phenotype.

Electronic supplementary material

The online version of this article (10.1186/s12864-018-4773-z) contains supplementary material, which is available to authorized users.

Novel avian leukosis virus-related endogenous proviruses from layer chickens: characterization and development of locus-specific assays

During the course of evolution, vertebrate genomes have been invaded and colonized by retroviruses. In humans, for example, endogenous retroviruses (long terminal repeat elements) occupy roughly twice as much sequence space as essential genes. There are numerous reports in the literature implicating endogenous proviruses in the modulation of host physiology. The fact that many of these host-virus interactions take place in a proviral locus-specific manner speaks to the need for rapid assays for element profiling. This report deals with the identification of novel elements belonging to a family of endogenous retroviruses, designated ALVE, that reside in the genome of the chicken and that are closely related to exogenous avian leukosis viruses. The study of ALVE elements in the chicken genome serves as a model system for understanding the interplay between endogenous viruses and their vertebrate hosts in general, including humans. In this report, we present locus-specific, diagnostic PCR-based assays for 2 novel ALVE elements. In addition, we characterize the proviral structures and examine the genomic environments of both novel elements along with a previously described element known as ALVE-NSAC-3.

Locus-specific diagnostic tests for endogenous avian leukosis-type viral loci in chickens

The genome of the chicken, Gallus gallus, contains endogenous proviral elements (ALVE elements or ev genes) that display a high degree of similarity to the Avian Leukosis class of retroviruses. The ALVE proviruses are known to modulate physiological processes of the host birds. Different ALVE elements retain variable portions of the complete, prototype viral genome, and each provirus resides in its own specific location within the host genome. Thus, each ALVE element has its own particular potential to modulate host physiology depending on the nature of its integration site, the completeness of the proviral genome, and the level of expression of the locus. It is important, therefore, to be able to establish the ALVE element profiles of chickens quickly and accurately, both in the laboratory and in a commercial setting. The current method of choice for simple, quick, and accurate typing is the polymerase chain reaction (PCR). This paper reviews the present status of PCR typing of ALVE proviruses and lists the assay protocols for 19 different elements. In addition, it compares the insertion sites of these elements in an effort to identify common motifs at ALVE integration sites.

A deleted retroviral insertion at the ev21-K complex locus in Indonesian chickens

Very poor feather development has been observed in chickens of the Nunukan strain, originating from Indonesia. The wing of the newly hatched chick does not show any primary or covert feathers; this phenotype will be referred to as very-late feathering (VLF). As adults, chickens are feathered but tail feathers are short and fragile. An experimental population was set up at the National Institute of Agronomic Research (INRA), Jouy-en-Josas, from one Nunukan male and four Nunukan females. Preliminary observations did not support the hypothesis of a sex-linked dominant mode of inheritance for the VLF phenotype. A restriction fragment length polymorphism (RFLP) study using five restriction enzymes and two probes, RAV-2 and endogenous virus (ev) ev21-int specific for the endogenous viral locus ALVE21, showed the presence of the expected 3' junction fragments for the ev21 occupied site but failed to reveal the expected 5' junction fragments for ev21 in Nunukan chickens. The unoccupied site corresponded to the ev21 unoccupied repeat (UR) of type a (URa). A deletion in the 5' region of the provirus and of the insertion site was indicated by the RFLP analysis and confirmed by a PCR study. Primers were designed in order to amplify a 5' junction fragment specific to the modified ev21 found in the Nunukan chickens. The sequence of this amplified product showed that the deletion started 652 bp upstream of the insertion site of ev21 and ended within the pol gene of the viral genome. This deletion represents a new allele, OSD, at the ev21 insertion site (locus ALVE21), that appears insufficient to produce a complete virus. Current data do not show a clear causal relationship between OSD and the VLF phenotype. The presence of OSD may be required but is not in itself sufficient to obtain the VLF phenotype. The genetic relationships between OSD and the altered feathering phenotype of Nunukan chickens will be investigated further in families segregating for the VLF phenotype, using the locus-specific PCR test developed as part of this study.

A restriction enzyme map of the sex-linked late-feathering locus of chickens

A 34-kb restriction endonuclease map of the region associated with an endogenous virus integration site and K, the gene that confers sex-linked late-feathering (LF) in chickens, is presented. Hybridizations of genomic blots of DNA from early-feathering and LF White Leghorns indicated that the region also contains additional repetitive elements upstream from a chicken repetitive (CR1) element. This extended map and the probes described should be useful in identifying the molecular alterations associated with this locus.

Organization of the sex-linked late-feathering haplotype in chickens

Nucleotide sequence analysis of polymerase chain reaction products confirmed that ev21 integrated into one of two large homologous elements on the Z chromosome of late-feathering (LF) White Leghorn chickens. Southern blots of NotI-, NaeI-, KspI- and BamHI-digested DNA from early-feathering (EF) and LF White Leghorns, that had been hybridized with a probe that flanks ev21, indicated a 180 kb duplication of an unoccupied repeat in the LF genotype of White Leghorns. A KspI fragment that carries ev21 was about 32 kb smaller than the KspI fragment found in EF DNA. In the evolution of LF, retroviral insertion into one of two large repeats and a 32 kb deletion may have generated LF.

Screening chickens for endogenous virus ev21 viral element by the polymerase chain reaction

The molecular architecture of the sex-linked late-feathering region of the chicken genome is still poorly defined. Current evidence points to a strong association between the presence of the endogenous viral element ev21 and the late-feathering phenotype. However, analysis at the molecular level has demonstrated that this is not a simple case of insertional mutagenesis. Instead, the structure of the region of the chicken genome containing the feathering locus is complex and variable between and within lines of chickens. Significant clues to the molecular structure of this genomic region can be obtained by analyzing rare and revertant genotypes. However, searching for rare genotypes can only be carried out effectively using quick screen methodology. This paper describes a quick, polymerase chain reaction-based test for ev21 that facilities the search for rare genotypes.

Determination of the zygosity of ev21-K in late-feathering male White Leghorns using the polymerase chain reaction

The dominant sex-linked late-feathering (LF) gene, K, is of commercial importance for sex determination at hatch. Knowledge of the zygosity of sequences associated with K would enable breeders to more efficiently select homozygous grandparent LF males on the maternal side of the standard feather-sex cross because all of their progeny would be LF, whereas only half of the progeny from heterozygous grandparent males would be LF. A specific, polymerase chain reaction (PCR) assay is described that distinguishes White Leghorn K/K males from K/k+ males and obviates the need to raise all LF grandparent males to sexual maturity. Because the Z chromosome of some LF broiler breeders have, in addition to the endogenous virus gene, ev21, the wild type allele, which is termed the unoccupied repeat b (URb), this approach may not be applicable to some broiler lines.

Application of a locus-specific DNA hybridization probe in the analysis of the slow-feathering endogenous virus complex of chickens

To investigate further the sex-linked, slow-feathering (SF) locus, a DNA hybridization probe that flanks the integration site of endogenous virus ev21 was used to probe Southern blots from a variety of commercial SF White Leghorn (WL), broiler, and endangered lines. After HaeIII digestion of DNA from SF WL, the 5' and 3' provirus-cell junction fragments were seen in addition to a 2.5-kb fragment of cell sequences that was homologous with the viral integration region. The latter polymorphism, which appeared to represent sequences duplicated after integration of EV21, was designated unoccupied repeat URa. Among SF broiler crosses, the same provirus-cell junction fragments were found but the pristine region that represented the 1.6-kb proviral URb was also found. Only URb was found among rapid-feathering (RF) chickens, regardless of breed. Although there was marked (greater than 95%), agreement between the presence of ev21-cell; junction fragments and the SF phenotype among both WL and broilers, Southern blots of DNA from a few commercial SF broiler chickens lacked ev21 junction fragments but some RF revertants harbored ev21 junction fragments. These anomalies suggest that ev21 may not be the sole determinant of the SF phenotype.