Genome wide analysis of 3' UTR sequence elements and proteins regulating mRNA stability during maternal-to-zygotic transition in zebrafish.

Posttranscriptional regulation plays a crucial role in shaping gene expression. During the maternal-to-zygotic transition (MZT), thousands of maternal transcripts are regulated. However, how different cis-elements and trans-factors are integrated to determine mRNA stability remains poorly understood. Here, we show that most transcripts are under combinatorial regulation by multiple decay pathways during zebrafish MZT. By using a massively parallel reporter assay, we identified cis-regulatory sequences in the 3' UTR, including U-rich motifs that are associated with increased mRNA stability. In contrast, miR-430 target sequences, UAUUUAUU AU-rich elements (ARE), CCUC, and CUGC elements emerged as destabilizing motifs, with miR-430 and AREs causing mRNA deadenylation upon genome activation. We identified trans-factors by profiling RNA-protein interactions and found that poly(U)-binding proteins are preferentially associated with 3' UTR sequences and stabilizing motifs. We show that this activity is antagonized by C-rich motifs and correlated with protein binding. Finally, we integrated these regulatory motifs into a machine learning model that predicts reporter mRNA stability in vivo.

Brd4 and P300 Confer Transcriptional Competency during Zygotic Genome Activation.

The awakening of the genome after fertilization is a cornerstone of animal development. However, the mechanisms that activate the silent genome after fertilization are poorly understood. Here, we show that transcriptional competency is regulated by Brd4- and P300-dependent histone acetylation in zebrafish. Live imaging of transcription revealed that genome activation, beginning at the miR-430 locus, is gradual and stochastic. We show that genome activation does not require slowdown of the cell cycle and is regulated through the translation of maternally inherited mRNAs. Among these, the enhancer regulators P300 and Brd4 can prematurely activate transcription and restore transcriptional competency when maternal mRNA translation is blocked, whereas inhibition of histone acetylation blocks genome activation. We conclude that P300 and Brd4 are sufficient to trigger genome-wide transcriptional competency by regulating histone acetylation on the first zygotic genes in zebrafish. This mechanism is critical for initiating zygotic development and developmental reprogramming.

Characterization of a pseudogene for murine methylenetetrahydrofolate reductase.

Methylenetetrahydrofolate reductase (MTHFR) reduces 5,10-methylenetetrahydrofolate to 5-methyltetrahydrofolate, the major carbon donor in the remethylation of homocysteine to methionine. Mild MTHFR deficiency, due to a common variant at nucleotide 677, has been reported to influence risk for several disorders including cardiovascular disease, neural tube defects, pregnancy complications and cancer. In recent work, we characterized the complete cDNA and gene sequences in the human and mouse genes, which had previously been mapped to chromosomes 1 and 4, respectively. During the course of this work, we observed that PCR primers in exons 1 and 2 of Mthfr generated amplicons of the expected size for the normal Mthfr transcript, using both reverse-transcribed RNA and genomic DNA as templates. These findings alluded to the existence of a pseudogene in the murine genome. Here, we report the characterization of this pseudogene. The absence of intron 1, the partial retention of intron 2, the location of this gene on chromosome 5, and the presence of sequences unrelated to Mthfr at the 5' and 3' ends of the 1259 bp fragment are features that are indicative of a partially-processed pseudogene, that we have designated Mthfr-ps. A Mthfr-ps transcript was not detectable by sensitive RT-PCR using assays designed to simultaneously detect the authentic Mthfr transcript. The structure of this paralogous gene and the identification of a repeat sequence at the 3' end of this pseudogene suggest that it arose by retrotransposition of a mis-spliced Mthfr transcript. Investigations of the Mthfr gene should take into account the presence of the non-functional Mthfr-ps to avoid misinterpretation of results.