Molecular correlates of hypothalamic development in songbird ontogeny in comparison with the telencephalon

Development of the songbird brain provides an excellent experimental model for understanding the regulation of sex differences in ontogeny. Considering the regulatory role of the hypothalamus in endocrine, in particular reproductive, physiology, we measured the structural (volume) and molecular corr...

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Bibliographic Details
Published inThe FASEB journal Vol. 34; no. 4; p. 4997
Main Authors Majumdar, Gaurav, Yadav, Garima, Hamaide, Julie, Coussement, Louis, De Meyer, Tim, Verhoye, Marleen, Vanden Berghe, Wim, Van Der Linden, Annemie, Balthazart, Jacques
Format Journal Article
LanguageEnglish
Published United States 01.04.2020
Subjects
Animals
Female
Finches
Gene Expression Regulation, Developmental
Hypothalamus - growth & development
Hypothalamus - metabolism
Male
Receptors, Thyroid Hormone - genetics
Receptors, Thyroid Hormone - metabolism
Sex Characteristics
Sexual Development
Telencephalon - growth & development
Telencephalon - metabolism
Transcriptome
telencephalon
zebra finch
hormones
ontogeny
hypothalamus
sexual dimorphism
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Summary:Development of the songbird brain provides an excellent experimental model for understanding the regulation of sex differences in ontogeny. Considering the regulatory role of the hypothalamus in endocrine, in particular reproductive, physiology, we measured the structural (volume) and molecular correlates of hypothalamic development during ontogeny of male and female zebra finches. We quantified by relative quantitative polymerase chain reaction (rqPCR) the expression of 14 genes related to thyroid and steroid hormones actions as well as 12 genes related to brain plasticity at four specific time points during ontogeny and compared these expression patterns with the expression of the same genes as detected by transcriptomics in the telencephalon. These two different methodological approaches detected specific changes with age and demonstrated that in a substantial number of cases changes observed in both brain regions are nearly identical. Other genes however had a tissue-specific developmental pattern. Sex differences or interactions of sex by age were detected in the expression of a subset of genes, more in hypothalamus than telencephalon. These results correlate with multiple known aspects of the developmental and reproductive physiology but also raise a number of new functional questions.
ISSN:1530-6860
DOI:10.1096/fj.201902477R