Changes in prolactin receptor homodimer availability may cause late feathering in chickens

•The dSPEF2 gene transcription occurs beyond all coding exons of the dPRLR gene.•The dSPEF2 gene transcription may repress the expression of dPRLR mRNA.•The K gene increases PRL receptor mRNAs with higher translation efficiency.•The PRLR/dPRLR ratio is low in embryos and high in hatched chicks in LF...

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Published in:General and comparative endocrinology 2019-02, Vol.272, p.109-116
Main Authors: Okamura, Ayako, Masumoto, Ayane, Takenouchi, Atsushi, Kudo, Toshiyuki, Aizawa, Sayaka, Ogoshi, Maho, Takahashi, Sumio, Tsudzuki, Masaoki, Takeuchi, Sakae
Format: Article
Language:English
Subjects:
5′UTR variant
Alternative splicing
Animals
Antisense RNA
Chickens - metabolism
Feathers - metabolism
Female
Prolactin receptor
Receptors, Prolactin - metabolism
Translation efficiency
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Summary:•The dSPEF2 gene transcription occurs beyond all coding exons of the dPRLR gene.•The dSPEF2 gene transcription may repress the expression of dPRLR mRNA.•The K gene increases PRL receptor mRNAs with higher translation efficiency.•The PRLR/dPRLR ratio is low in embryos and high in hatched chicks in LF chickens.•Modulation of PRL receptor signaling by the K gene causes the chicken LF phenotype. Chicken early (EF) and late feathering (LF) are sex-linked phenotypes conferred by wild-type k+ and dominant K alleles on chromosome Z, respectively. Besides prolactin (PRL) receptor (PRLR) and sperm flagellar 2 (SPEF2) genes, the K allele contains a fusion gene in which partially duplicated PRLR (dPRLR) and SPEF2 (dSPEF2) genes are linked in a tail-to-tail manner. The causative dPRLR gene encodes a C-terminal truncated receptor. LF chickens have short or no primaries at hatching; however, their feather growth rate is higher than that of EF chickens. This study aimed to elucidate the molecular basis of the K allele’s biphasic effect on feather development. By 3′RACE and RT-PCR analyses, we demonstrated that dSPEF2 gene transcription occurred beyond all coding exons of the dPRLR gene on the opposite strand and that dPRLR mRNA was less abundant than PRLR mRNA. In addition, a 5′UTR splice variant (SPV) of PRL receptor mRNAs was increased in LF chickens. In vitro expression analysis of 5′UTR linked to the luciferase reporter gene revealed higher translation efficiency of SPV. RT-qPCR showed that the dPRLR mRNA level was higher in embryos; conversely, SPV was higher in hatched chickens, as was dSPEF2 mRNA. These findings suggest that the K allele inhibits feather development at the fetal stage by expressing dPRLR to attenuate PRLR function and promotes feather growth after hatching by increasing PRLR through dSPEF2 mRNA expression. Increased SPV may cause greater feather growth than that in EF chickens by increasing the availability of PRLR homodimers and enhancing PRL signaling.
ISSN:0016-6480
1095-6840
DOI:10.1016/j.ygcen.2018.12.011