The microRNAs (miRNAs) are a newly identified class of small non-protein-coding regulatory RNA. Using comparative genomics, we identified 69 miRNAs belonging to 33 families in the domesticated soybean (Glycine max) as well as five miRNAs in the soybean wild species Glycine soja and Glycine clandestine. TaqMan((R)) MicroRNA Assay analyses demonstrated that these miRNAs were differentially expressed in soybean tissues, with certain classes expressed preferentially in both a spatiotemporal and a tissue-specific manner. Detailed sequence analyses revealed that soybean pre-miRNAs vary in length from 44 to 259 nt with an average of 106 +/- 45 nt, harbor mature miRNAs that differ in their physical location within the pre-miRNAs, and encode more than a single mature miRNA. Comparative sequence analyses of soybean miRNA sequences showed that uracil is the dominant base in the first position at the 5' end of the mature miRNAs while cytosine is dominant at the 19th position, which is indicative that these two bases may have an important functional role in miRNA biogenesis and/or miRNA-mediated gene regulation. Soybeans were unique among plants in the frequency of occurrence of miRNA clusters. For the first time, antisense miRNAs were identified in plants. The five antisense miRNAs and their sense partners from soybean belonged to three miRNA families (miR-157, miR-162 and miR-396). Antisense miRNAs were also identified in soybean wild species. Mature antisense miRNA products appeared to have 1-3 nucleotide changes compared to their sense partners, which suggests that both strands of a miRNA gene can produce functional mature miRNAs and that antisense transcripts may differ functionally from their sense partners. Based on previously established in silico methods, we predicted 152 miRNA-targeted mRNAs, which included a large percentage of mRNAs that encode transcription factors that regulate plant growth and development as well as a lesser percentage of mRNAs that encode environmental signal transduction proteins and central metabolic processes.
The study of Hox clusters and genes provides insights into the evolution of genomic regulation of development. Derived ray-finned fishes (Actinopterygii, Teleostei) such as zebrafish and pufferfish possess duplicated Hox clusters that have undergone considerable sequence evolution. Whether these changes are associated with the duplication(s) that produced extra Hox clusters is unresolved because comparison with basal lineages is unavailable. We sequenced and analyzed the HoxA cluster of the bichir (Polypterus senegalus), a phylogenetically basal actinopterygian. Independent lines of evidence indicate that bichir has one HoxA cluster that is mosaic in its patterns of noncoding sequence conservation and gene retention relative to the HoxA clusters of human and shark, and the HoxA␣ and HoxA clusters of zebrafish, pufferfish, and striped bass. HoxA cluster noncoding sequences conserved between bichir and euteleosts indicate that novel cis-sequences were acquired in the stem actinopterygians and maintained after cluster duplication. Hence, in the earliest actinopterygians, evolution of the single HoxA cluster was already more dynamic than in human and shark. This tendency peaked among teleosts after HoxA cluster duplication.
Progestins, progesterone derivatives, are the most critical signaling steroid for initiating final oocyte maturation (FOM) and ovulation, in order to advance fully-grown immature oocytes to become fertilizable eggs in basal vertebrates. It is well-established that progestin induces FOM at least partly through a membrane receptor and a non-genomic steroid signaling process, which precedes progestin triggered ovulation that is mediated through a nuclear progestin receptor (Pgr) and genomic signaling pathway. To determine whether Pgr plays a role in a non-genomic signaling mechanism during FOM, we knocked out Pgr in zebrafish using transcription activator-like effector nucleases (TALENs) and studied the oocyte maturation phenotypes of Pgr knockouts (Pgr-KOs). Three TALENs-induced mutant lines with different frame shift mutations were generated. Homozygous Pgr-KO female fish were all infertile while no fertility effects were evident in homozygous Pgr-KO males. Oocytes developed and underwent FOM normally in vivo in homozygous Pgr-KO female compared to the wild-type controls, but these mature oocytes were trapped within the follicular cells and failed to ovulate from the ovaries. These oocytes also underwent normal germinal vesicle breakdown (GVBD) and FOM in vitro, but failed to ovulate even after treatment with human chronic gonadotropin (HCG) or progestin (17α,20β-dihydroxyprogesterone or DHP), which typically induce FOM and ovulation in wild-type oocytes. The results indicate that anovulation and infertility in homozygous Pgr-KO female fish was, at least in part, due to a lack of functional Pgr-mediated genomic progestin signaling in the follicular cells adjacent to the oocytes. Our study of Pgr-KO supports previous results that demonstrate a role for Pgr in steroid-dependent genomic signaling pathways leading to ovulation, and the first convincing evidence that Pgr is not essential for initiating non-genomic progestin signaling and triggering of meiosis resumption.
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