Ectopically expressed Slc34a2a sense-antisense transcripts cause a cerebellar phenotype in zebrafish embryos depending on RNA complementarity and Dicer.

Monica J Piatek,Amy Fearn,Bill Chaudhry,Victoria Henderson,Andreas Werner,Stephan C.F Neuhauss

doi:10.1371/journal.pone.0178219

Monica J Piatek, Amy Fearn + Show 4 more

Open Access

https://doi.org/10.1371/journal.pone.0178219

Copy DOI

Journal: PloS one	Publication Date: May 18, 2017
Citations: 9	License type: CC BY 4.0

Affiliation: Newcastle University, Centre for Life

Abstract

Natural antisense transcripts (NATs) are complementary to protein coding genes and potentially regulate their expression. Despite widespread occurrence of NATs in the genomes of higher eukaryotes, their biological role and mechanism of action is poorly understood. Zebrafish embryos offer a unique model system to study sense-antisense transcript interplay at whole organism level. Here, we investigate putative antisense transcript-mediated mechanisms by ectopically co-expressing the complementary transcripts during early zebrafish development. In zebrafish the gene Slc34a2a (Na-phosphate transporter) is bi-directionally transcribed, the NAT predominantly during early development up to 48 hours after fertilization. Declining levels of the NAT, Slc34a2a(as), coincide with an increase of the sense transcript. At that time, sense and antisense transcripts co-localize in the endoderm at near equal amounts. Ectopic expression of the sense transcript during embryogenesis leads to specific failure to develop a cerebellum. The defect is RNA-mediated and dependent on sense-antisense complementarity. Overexpression of a Slc34a2a paralogue (Slc34a2b) or the NAT itself had no phenotypic consequences. Knockdown of Dicer rescued the brain defect suggesting that RNA interference is required to mediate the phenotype. Our results corroborate previous reports of Slc34a2a-related endo-siRNAs in two days old zebrafish embryos and emphasize the importance of coordinated expression of sense-antisense transcripts. Our findings suggest that RNAi is involved in gene regulation by certain natural antisense RNAs.

Highlights

Long non-coding RNAs play an essential role in coordinating the spatio-temporal transcription of complex genomes
We have found previously that Slc34a2a sense and antisense transcripts are co-expressed in zebrafish embryos at around two days post fertilization
In line with previous end-point PCR data [26], we found a gradual increase of the Slc34a2a sense transcript with a parallel decrease of the antisense transcript (Fig 1B)

Summary

Introduction

Long non-coding RNAs (lncRNAs) play an essential role in coordinating the spatio-temporal transcription of complex genomes. Co-expressed sense/antisense transcripts can hybridize and potentially feed into double stranded RNA (dsRNS) mediated pathways. The biological relevance of dsRNA intermediates is supported by the observation that sense and antisense transcripts are usually detected in the same RNA preparation [4] and by recent reports focussing on specific bi-directionally transcribed genes. In vertebrates up to 72% of genomic loci show evidence of bi-directional transcription and potentially express NATs [5]. These are enriched in testis, in haploid spermatids, but are found in somatic cells of all tissues [6, 7]. Gene arrangements that give rise to sense-antisense hybrids are significantly under represented on the mammalian X chromosome [8, 9]

Objectives

Methods

Results

Discussion

Conclusion