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Adenosine methylation of messenger RNA at the N6 position (m6A) is a non-editing modification that can affect several aspects of mRNA metabolism. Dm Ime4, also known as METTL3, MTA, and MTA-70 in other organisms, is the catalytic subunit of the methyltransferase complex that adds this modification. Dm ime4 is evolutionarily conserved and essential for development in metazoans and plants. Because of its pleiotropic effects, it has been difficult to establish the main reason why embryonic arrest occurs in plants, mice, and zebrafish. Using a strategy that depletes Dm Ime4 specifically in the somatic cyst cells of Drosophila testes without affecting essential functions in development, our lab has found that Dm Ime4 may potentially regulate splicing of profilin (chic) mRNA, the message for an essential and evolutionarily conserved protein mainly known for its function in actin polymerization. One of the lesser known roles for Chic is its requirement for establishment and maintenance of the somatic cyst-cell permeability barrier in Drosophila spermatogenesis. Chic and Dm Ime4 colocalize and are abundant in somatic cyst cells throughout spermatogenesis. Upon selective depletion of Dm Ime4, we observe significant reduction of Chic protein levels and malfunction of the permeability barrier. We have found that chic mRNA contains intronic Dm Ime4 binding sites that can form the hairpin structures required for recognition by the methyltransferase complex. Our data show that the reduced levels of Chic protein observed in Dm ime4 somatic cyst-cell knockdowns could be the result of aberrant splicing of its mRNA. In turn, low levels of Chic are known to affect the function of the somatic permeability barrier, leading to germline death and the reduced fertility observed in Dm ime4 knockdown males. We propose that Dm Ime4 may regulate chic in other developmental contexts and in other organisms, including mice and humans. Chic is an essential protein that is evolutionarily conserved, and establishment and maintenance of cell barriers and domains are important strategies used in metazoan development. Taken together, our findings define a framework to investigate specific functions of Dm Ime4 and its homologs in multicellular organisms by bypassing its pleiotropic requirement in early developmental stages.

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Our understanding of the biological role of N 6-methyladenosine (m6A), a ubiquitous non-editing RNA modification, has increased greatly since 2011. More recently, work from several labs revealed that m6A methylation regulates several aspects of mRNA metabolism. The "writer" protein METTL3, known as MT-A70 in humans, DmIme4 in flies, and MTA in plants, has the catalytic site of the METTL3/14/16 subunit of the methyltransferase complex that includes many other proteins. METTL3 is evolutionarily conserved and essential for development in multicellular organisms. However, until recently, no study has been able to provide a mechanism that explains the essentiality of METTL3. The addition of m6A to gene transcripts has been compared with the epigenetic code of histone modifications because of its effects on gene expression and its reversibility, giving birth to the field of epitranscriptomics, the study of the biological role of this and similar RNA modifications. Here, we focus on METTL3 and its likely conserved role in profilin regulation in neurogenesis. However, this and many other subunits of the methyltransferase complex are starting to be identified in several developmental processes and diseases. A recent plethora of studies about the biological role of METTL3 and other components of the methyltransferase complex that erase (FTO) or recognize (YTH proteins) this modification on transcripts revealed that this RNA modification plays a variety of roles in many biological processes like neurogenesis. Our work in Drosophila shows that the ancient and evolutionarily conserved gene profilin (chic in Drosophila) is a target of the m6A writer. Here, we discuss the implications of our study in Drosophila and how it unveils a conserved mechanism in support of the essential function of METTL3 in metazoan development. Profilin (chic) is an essential gene of ancient evolutionary origins, present in sponges (Porifera), the oldest still extant metazoan phylum of the common metazoan ancestor Urmetazoa. We propose that the relationship between profilin and METTL3 is conserved in metazoans and it provides insights into possible regulatory roles of m6A modification of profilin transcripts in processes such as neurogenesis.

RESUMEN

In Drosophila melanogaster, viability assays are used to determine the fitness of certain genetic backgrounds. Allelic variations can result in partial or complete loss of viability at different stages of development. Our lab has developed a method to assess viability in Drosophila from embryo to fully mature adult. The method relies on quantifying the number of progeny present at different stages during development, starting with hatched embryos. After embryos have been quantified, additional stages are counted, including L1/L2, pupae, and mature adults. After all stages have been examined, a statistical analysis such as the chi-square test is used to determine if there is a significant difference between the starting number of progeny (hatched embryos) and later stages culminating in the observed number of adults, thus rejecting or accepting the null hypothesis (that the number of hatched embryos will be equal to the number of larvae, pupae, and adults recorded throughout the stages of development). The primary advantage of this assay is its simplicity and accuracy, as it does not require an embryo rinse to transfer them to the food vial, avoiding losses from technical errors. Although the protocol described here does not directly examine L2/L3 larvae, additional steps can be added to account for these. Comparing the number of hatched embryos, L1, pupae, and adults can help determine if viability was compromised during the L2/L3 stages for further studies (the use of colored food helps with visual identification of larvae). Overall, this method can help Drosophila researchers and educators determine when viability is compromised during the fly life cycle. Routine assessment of stocks using this assay can prevent accumulation of secondary mutations that may affect the phenotype of the originally isolated mutant, especially if the original mutations affect fitness. For this reason, our lab maintains multiple copies of each of our Dm ime4 alleles and routinely checks the purity of each stock with this method in addition to other molecular analyses.

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The intestinal epithelium has constant turnover throughout the life of the organ, with apoptosis of cells at the tips of folds or villi releasing cells into the lumen. Due to constant turnover, epithelial cells need to be constantly replaced. Epithelial cells are supplied by stem cell niches that form at the base of the interfold space (zebrafish) and crypts (birds and mammals). Within the adult stem cell niche of mammals, secretory cells such as Paneth and goblet cells play a role in modulation of proliferation and stem cell activity, producing asymmetric divisions. Progeny of asymmetric divisions move up the fold or villi, giving rise to all of the epithelial cell types. Although much is known about function and organization of the adult intestinal stem cell niche, less is understood about regulation within the immature stem cell compartment. Following smooth muscle formation, the intestinal epithelium folds and proliferation becomes restricted to the interfold base. Symmetric divisions continue in the developing interfold niche until stem cell progeny begin asymmetric divisions, producing progeny that migrate up the developing folds. Proliferative progeny from the developing stem cell niche begin migrating out of the niche during the third week post-embryogenesis (zebrafish) or during the postnatal period (mammals). Regulation and organization of epithelial proliferation in the immature stem cell niche may be regulated by signals comparable to the adult niche. Here we identify a novel subset of secretory cells associated with the developing stem cell niche that receive Notch signaling (referred to as NRSCs). Inhibition of the embryonic NRSCs between 74 hpf to 120 hpf increases epithelial proliferation as well as EGF and IGF signaling. Inhibition of post-embryonic NRSCs (6 hpf to 12 dpf) also increases epithelial proliferation and expression level of Wnt target genes. We conclude that NRSCs play a role in modulation of epithelial proliferation through repression of signaling pathways that drive proliferation during both embryogenesis and the post embryonic period.

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The vertebrate intestinal epithelium is renewed continuously from stem cells at the base of the crypt in mammals or base of the fold in fish over the life of the organism. As stem cells divide, newly formed epithelial cells make an initial choice between a secretory or enterocyte fate. This choice has previously been demonstrated to involve Notch signaling as well as Atonal and Her transcription factors in both embryogenesis and adults. Here, we demonstrate that in contrast to the atoh1 in mammals, ascl1a is responsible for formation of secretory cells in zebrafish. ascl1a-/- embryos lack all intestinal epithelial secretory cells and instead differentiate into enterocytes. ascl1a-/- embryos also fail to induce intestinal epithelial expression of deltaD suggesting that ascl1a plays a role in initiation of Notch signaling. Inhibition of Notch signaling increases the number of ascl1a and deltaD expressing intestinal epithelial cells as well as the number of developing secretory cells during two specific time periods: between 30 and 34hpf and again between 64 and 74hpf. Loss of enteroendocrine products results in loss of anterograde motility in ascl1a-/- embryos. 5HT produced by enterochromaffin cells is critical in motility and secretion within the intestine. We find that addition of exogenous 5HT to ascl1a-/- embryos at near physiological levels (measured by differential pulse voltammetry) induce anterograde motility at similar levels to wild type velocity, distance, and frequency. Removal or doubling the concentration of 5HT in WT embryos does not significantly affect anterograde motility, suggesting that the loss of additional enteroendocrine products in ascl1a-/- embryos also contributes to intestinal motility. Thus, zebrafish intestinal epithelial cells appear to have a common secretory progenitor from which all subtypes form. Loss of enteroendocrine cells reveals the critical need for enteroendocrine products in maintenance of normal intestinal motility.

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N(6)-methyladenosine is a nonediting RNA modification found in mRNA of all eukaryotes, from yeast to humans. Although the functional significance of N(6)-methyladenosine is unknown, the Inducer of MEiosis 4 (IME4) gene of Saccharomyces cerevisiae, which encodes the enzyme that catalyzes this modification, is required for gametogenesis. Here we find that the Drosophila IME4 homolog, Dm ime4, is expressed in ovaries and testes, indicating an evolutionarily conserved function for this enzyme in gametogenesis. In contrast to yeast, but as in Arabidopsis, Dm ime4 is essential for viability. Lethality is rescued fully by a wild-type transgenic copy of Dm ime4 but not by introducing mutations shown to abrogate the catalytic activity of yeast Ime4, indicating functional conservation of the catalytic domain. The phenotypes of hypomorphic alleles of Dm ime4 that allow recovery of viable adults reveal critical functions for this gene in oogenesis. Ovarioles from Dm ime4 mutants have fused egg chambers with follicle-cell defects similar to those observed when Notch signaling is defective. Indeed, using a reporter for Notch activation, we find markedly reduced levels of Notch signaling in follicle cells of Dm ime4 mutants. This phenotype of Dm ime4 mutants is rescued by inducing expression of a constitutively activated form of Notch. Our study reveals the function of IME4 in a metazoan. In yeast, this enzyme is responsible for a crucial developmental decision, whereas in Drosophila it appears to target the conserved Notch signaling pathway, which regulates many vital aspects of metazoan development.

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Entry into meiosis is a key developmental decision. We show here that meiotic entry in Saccharomyces cerevisiae is controlled by antisense-mediated regulation of IME4, a gene required for initiating meiosis. In MAT a/alpha diploids the antisense IME4 transcript is repressed by binding of the a1/alpha2 heterodimer at a conserved site located downstream of the IME4 coding sequence. MAT a/alpha diploids that produce IME4 antisense transcript have diminished sense transcription and fail to initiate meiosis. Haploids that produce the sense transcript have diminished antisense transcription and manifest several diploid phenotypes. Our data are consistent with transcription interference as a regulatory mechanism at the IME4 locus that determines cell fate.

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