Gene regulation of early developmental processes of haploid and diploid embryos of Apis mellifera

Embryonic development is the result of a precisely controlled sequence of events modulated by environmental signals and intracellular mechanisms. In Hymenoptera, this process takes a special character due the sex-determination system (haplodiploidy). In this system, fertilized eggs develop in females (diploid) and unfertilized eggs in males (haploid). Thus, important events such as egg activation and maternal-zygotic transition, events of the early embryogenesis are key elements to understand the development of both types of embryos. Egg activation is a complex event triggered in response to external stimuli and necessary for the onset of embryogenesis. In honeybees egg activation occurs independently of fertilization and seems to be triggered during the passage through mother\'s reproductive tract. Furthermore, if the egg is not fertilized it will develop into haploid organism. However, if the egg receives the sperm up to 30min after activation, this egg develops into a diploid organism. In Drosophila, the egg activation is also fertilization independent. Initial stimulus that triggers the development is due mechanical stresses suffered by the egg during ovulation and passage through the reproductive tract. In this model, the first activation signal includes activation of calciumdependent pathway. Maternal molecules that are incorporated into the oocyte during ovogenesis, act during egg activation, as well as in early embryogenesis. Early embryogenesis events are also characterized by absence of high levels of zygotic transcription. The deposited molecules drive egg activation, breaking cell division dormancy permitting the beginning of embryonic development. But, the developing embryo gradually degrades and substitutes these mother-inherited molecules, in a process known as mother-to-zygote transition. Our main objective was the understanding of the deep crosstalk among the inherited molecules and the newly ones produced during the first steps of Apis mellifera embryogenesis. To achieve our objective 16 deep sequenced RNA (mRNA, miRNA) libraries were constructed using different age diploid and haploid embryos, and mature oocytes. Genome-wide transcriptome analysis was performed and interactive regulatory networks were constructed. Our analysis permitted the identification of maternal and zygotic mRNAs and miRNAs and related processes. Based on expression profiles of mRNAs and miRNAs in mature oocytes and haploid and diploid embryos of 2, 6 and 18-24 h of development, we constructed integrative regulatory networks (miRNA:mRNA) showing that the same miRNA could target different mRNAs in each type of embryo, in the same phase of development. As example we cite broad/GB48272, which is classified as maternal in diploid embryos and regulated by four different miRNAs. However, in haploid embryos it is zygotic and regulated by only one miRNA. Analysis of RNAseq and in situ hybridization showed the expression pattern of zelda in early honeybee embryos. Zelda is a key activator of Drosophila early zygotic genome and regulates important events in early embryogenesis binding to TAGteam motif. In A. mellifera, we found a putative TAGteam motif that has been implicated in early zygotic transcription. Moreover, in situ hybridization and PCR assay showed three pri-miRNAs (ame-mir-375-3p, ame-mir-34-5p and ame-mir-263b-5p) expressed during cleavage. The presence of pri-miRNAs is the first evidence of early zygotic transcription during cleavage. In short, we could say that this is the first work on Apis mellifera describing the early embryonic developmental events comparing haploid and diploid embryos using modern bioinformatics tools and advanced molecular analysis. (AU)