A new molecular mechanism supports that blue-greenish egg color evolved independently across chicken breeds.

Chicken blue-greenish coloration (BGC) was known as a classic Mendel trait caused by a retrovirus (EAV-HP) insertion in the SLCO1B3 gene. Lueyang black-boned chicken (LBC) BGC is light and varies continuously, implying that LBC BGC may be controlled by a new molecular mechanism. The aim of this study was to provide an insight into the molecular basis of LBC BGC. The EAV-HP was detected in the BGC (n = 105) and non-BGC LBC (n = 474) using a PCR-based method. The association of SLCO1B3 expression in shell glands and sequence variants in a 1.6-kb region upstream from the transcription start site of SLCO1B3 with eggshell color and biliverdin (pigment for BGC) concentration was studied. Promoter activities of haplotypes in the 1.6-kb region were analyzed by luciferase reporter assay. This study did not found the EAV-HP in BGC and Non-BGC LBC, but detected a strong positive correlation between levels of SLCO1B3 expression in shell glands and biliverdin concentrations. A total of 31 SNP were found in the 1.6-kb region. Twenty-two of 31 SNP formed 42 types of haplotypes in the re-sequenced samples (n = 94). Haplotype 4 was present in higher frequency in the BGC (52%) than Non-BGC (3%). Haplotype 13 was significantly associated with Non-BGC (Non-BGC vs. BGC = 26% vs. 6%). In line with the above associations, Haplotype 4 showed higher (P < 0.05) levels of SLCO1B3 expression in shell glands, biliverdin concentration, and promoter activity than Haplotype 13. This study confirms that LBC BGC is not caused by the EAV-HP, but remains to be associated with the change of SLCO1B3 expression. Haplotype 4 accounts to some extents for the molecular basis of LBC BGC. The new molecular mechanism supports LBC BGC independently evolved.

An EAV-HP insertion in the 5' flanking region of SLCO1B3 is associated with its tissue-expression profile in blue-eggshell Yimeng chickens (Gallus gallus).

We previously reported that blue eggshell color in chickens is associated with a partial endogenous retroviral (EAV-HP) insertion in the promoter region of the solute carrier organic anion transporter family member 1B3 (SLCO1B3) gene. The EAV-HP sequence includes numerous regulatory elements, which may modulate the expression of adjacent genes. To determine whether this insertion influences the expression of neighboring genes, we screened the expression of solute carrier organic anion transporter family members 1C1, 1B1 (SLCO1C1, SLCO1B1), and SLCO1B3 in 13 and 10 tissues from female and male Yimeng chickens, respectively. We observed that the insertion only significantly modulated the expression of SLCO1B3 and did not majorly affect that of SLCO1C1 and SLCO1B1. High expression of SLCO1B3 was detected in the shell gland, magnum, isthmus, and vagina of the oviduct in female blue-eggshell chickens. We also observed ectopic expression of SLCO1B3 in the testes of male chickens. SLCO1B3 is typically highly expressed in the liver; however, the EAV-HP insertion significantly reduces SLCO1B3 expression. As a liver-specific transporter, a reduction in the expression of SLCO1B3 may affect liver metabolism, particularly that of bile acids. We also detected higher ectopic expression of SLCO1B3 in the lungs of birds heterozygous for the EAV-HP insertion than in homozygous genotypes. In conclusion, we confirmed that the EAV-HP insertion modifies SLCO1B3 expression, and showed, for the first time, similar expression profile of this gene in all parts of the oviduct in females and testis in males. We also observed different levels of SLCO1B3 expression in the liver, which were associated with the EAV-HP insertion, and significantly higher expression in the lungs of birds with heterozygous genotype. The effects of these changes in the SLCO1B3 expression pattern on the function of the tissues warrant further investigation.

[CRISPR/Cas9-mediated foreign gene targeted knock-in into the chicken EAV-HP genome].

The study aims to use CRISPR/Cas9 introducing foreign gene targeted knock-in into chicken EAV-HP genome. First, specific primers were designed for amplification of EAV-HP left, right homologous arms and enhanced green fluorescent protein (eGFP) expression cassette. PCR products of homologous arms were ligated to both sides of eGFP by overlap extension PCR, resulting in full-length donor DNA fragment designated as LER. Then LER fragments were cloned into pMD19-T to obtain donor vector pMDT-LER. Subsequently, the donor vector pMDT-LER was transfected into HEK293T cells to verify the expression of eGFP gene. Furthermore, co-transfection of CRISPR/Cas9 expression vector and pMDT-LER into chicken DF-1 cells was performed to achieve eGFP transgenic cells. Meanwhile, eGFP expression was observed in cells, and the event of eGFP integration into EAV-HP genome was detectable by amplification of target DNA. Finally, the transgenic DF-1 cells were passaged seven times, and the stable integration and expression of eGFP was checked by PCR and Western blotting. These results demonstrated that eGFP gene was knocked into the EAV-HP genome successfully, which provides a new integration site for research of transgenic chicken.

CRISPR/Cas9-mediated foreign gene targeted knock-in into the chicken EAV-HP genome / 生物工程学报

The study aims to use CRISPR/Cas9 introducing foreign gene targeted knock-in into chicken EAV-HP genome. First, specific primers were designed for amplification of EAV-HP left, right homologous arms and enhanced green fluorescent protein (eGFP) expression cassette. PCR products of homologous arms were ligated to both sides of eGFP by overlap extension PCR, resulting in full-length donor DNA fragment designated as LER. Then LER fragments were cloned into pMD19-T to obtain donor vector pMDT-LER. Subsequently, the donor vector pMDT-LER was transfected into HEK293T cells to verify the expression of eGFP gene. Furthermore, co-transfection of CRISPR/Cas9 expression vector and pMDT-LER into chicken DF-1 cells was performed to achieve eGFP transgenic cells. Meanwhile, eGFP expression was observed in cells, and the event of eGFP integration into EAV-HP genome was detectable by amplification of target DNA. Finally, the transgenic DF-1 cells were passaged seven times, and the stable integration and expression of eGFP was checked by PCR and Western blotting. These results demonstrated that eGFP gene was knocked into the EAV-HP genome successfully, which provides a new integration site for research of transgenic chicken.

Molecular phylogenetic analysis of Chinese indigenous blue-shelled chickens inferred from whole genomic region of the SLCO1B3 gene.

In total, 246 individuals from 8 Chinese indigenous blue- and brown-shelled chicken populations (Yimeng Blue, Wulong Blue, Lindian Blue, Dongxiang Blue, Lushi Blue, Jingmen Blue, Dongxiang Brown, and Lushi Brown) were genotyped for 21 SNP markers from the SLCO1B3 gene to evaluate phylogenetic relationships. As a representative of nonblue-shelled breeds, White Leghorn was included in the study for reference. A high proportion of SNP polymorphism was observed in Chinese chicken populations, ranging from 89% in Jingmen Blue to 100% in most populations, with a mean of 95% across all populations. The White Leghorn breed showed the lowest polymorphism, accounting for 43% of total SNPs. The mean expected heterozygosity varied from 0.11 in Dongxiang Blue to 0.46 in Yimeng Blue. Analysis of molecular variation (AMOVA) for 2 groups of Chinese chickens based on eggshell color type revealed 52% within-group and 43% between-group variations of the total genetic variation. As expected, FST and Reynolds' genetic distance were greatest between White Leghorn and Chinese chicken populations, with average values of 0.40 and 0.55, respectively. The first and second principal coordinates explained approximately 92% of the total variation and supported the clustering of the populations according to their eggshell color type and historical origins. STRUCTURE analysis showed a considerable source of variation among populations for the clustering into blue-shelled and nonblue-shelled chicken populations. The low estimation of genetic differentiation (FST) between Chinese chicken populations is possibly due to a common historical origin and high gene flow. Remarkably similar population classifications were obtained with all methods used in the study. Aligning endogenous avian retroviral (EAV)-HP insertion sequences showed no difference among the blue-shelled chickens.