Project description:Background: The early stages of D. melanogaster embryogenesis involve cell migration and pattern formation, and lead to the formation of three germ layers (the ectoderm, mesoderm and endoderm). These developmental events are controlled by differential gene activity. In the current study we used a suppressive subtractive hybridization (SSH) procedure to identify a group of genes potentially involved in D. melanogaster early embryogenesis and to study the temporal activity of developmentally regulated genes at five different intervals covering 12 stages of embryogenesis. Results: Macroarrays were constructed to confirm induction of expression and determine the temporal profile of isolated subtracted cDNAs during embryo development. We identified a set of 118 genes that significantly increased their expression levels at least at one developmental interval compared with the reference interval. 53.4% of them have a phenotype and/or molecular function reported in the literature, whereas 46.6% are essentially uncharacterized. Clustering analysis revealed demarcated transcript groups with maximum gene activity at distinct developmental intervals. In situ hybridization assays were carried out on 30 of the transcripts and of these, 19 (63%) proved to have restricted expression patterns. 11 of the uncharacterized genes that exhibited temporal and spatially restricted patterns of expression in developing embryos encode putative secreted and transmembrane proteins. For three of them we validated our protein sequence predictions by expressing their cDNAs in S2R+ cells and analyze the subcellular distribution of recombinant proteins. Conclusions: Our data provides a list of developmentally regulated D. melanogaster genes and their expression profiles during embryogenesis, including novel information on the temporal and spatial expression patterns of several previously uncharacterized genes. In particular, we recovered a significant number of novel genes encoding putative secreted and transmembrane proteins, suggesting new components of signalling pathways that might be incorporated within the existing regulatory networks controlling Drosophila embryogenesis; they are also good candidates for more functional targeted analyses. Keywords: Drosophila melanogaster, gastrulation, macroarray, developmental time course We generated a subtracted stage specific cDNA library representing genes differentially expressed between Drosophila melanogaster synciyial blastoderm and gastrula stages. Clones were spotted onto nylon membranes and hybridized against cDNA probes representing mRNA from embryos at five different developmental intervals, in order to obtain time course expression data covering the first 12 stages of Drosophila development. We designed macroarrays containing either 302 non-redundant cDNAs, including protein-coding sequences, ncRNA, transposons, introns and intergenic regions (membranes A, B and C) and the complete subtracted library (579 cDNAs, membrane D). Each clone was spotted in duplicate. The following controls were spotted onto membranes: (1) a fragment of the vector pBluescript II obtained by amplification with the T7 and SP6 universal primers; (2) several spots of DMSO 50% (solvent used); (3) PCR amplified fragment of genes serendipity α, twist, tinman, fog and snail as positive controls, and (4) actin, tubulin, and RP49 as housekeeping, and (5) four dilutions of a PCR amplified fragment from a B. subtilis dap cDNA (ATCC; number 87486), which hybridizes to an in vitro synthesized poly(A)-RNA that was added to the embryo RNA samples (dilution 1/200) prior to the labelling process and used as spike mRNA (Kane et al., 2000).

Project description:First described in Drosophila melanogaster, planar cell polarity (PCP) is a developmental process essential for embryogenesis and development of polarized structures in Metazoans. This signaling pathway involves a set of evolutionarily conserved genes encoding transmembrane (Vangl, Frizzled, Celsr) and cytoplasmic (Prickle, Dishevelled) molecules. Vangl2 is of major importance in embryonic development as illustrated by its pivotal role during neural tube closure in human, mouse, Xenopus and zebrafish embryos. The regulated and poorly understood traffic of Vangl2 to the plasma membrane is a key event for its function in development. Here we identify a novel N-terminally extended isoform of Vangl2, termed Vangl2-Long that arises from the use of non-AUG start codon upstream of the coding region of canonical Vangl2. Vangl2-Long contains an evolutionarily conserved N-terminal 48 amino acid sequence bearing a signal for subcellular localization in the Golgi apparatus. Moreover, we provide data in Xenopus showing that Vangl2-Long is important for correct convergent extension movements and neural tube closure. These data describe a further level of complexity in Vangl2 expression, trafficking and function.

Project description:Drosophila melanogaster developmental transcriptome of whole body thorugh embryogenesis

Project description:Embryogenesis in rice shows a non-stereotypic cell division pattern, the formation of dorsal-ventral polarity, and endogenous initiation of the radicle, which differs from most dicotyledonous plants. To reveal the transcriptional features associated with developmental events during early embryogenesis in rice, we obtained transcriptome data, including the spatial and temporal data sets, using microarray experiments combined with a laser microdissection. We could predict the spatial expression foci of each expressed gene in the globular embryo, which revealed that the expression bias along the apical-basal and dorsal-ventral axes was correlated with temporal changes in expression levels during early embryogenesis. The spatial expression patterns of transcripts was suggestive of a potential contribution of phytohormone-related genes to early embryogenesis and was a characteristic feature of transcription factor genes. We also analyzed the relationship between expression sites of the genes in the globular embryo and those in embryonic organs at later stages. Based on in silico prediction of gene expression sites, we developed potential marker genes expressed in specific domains of the early embryo. The results and database will provide a framework for spatio-temporal gene expression in rice embryogenesis and increase our understanding of developmental diversity of plant embryogenesis.

Project description:The success of neopteran insects, with 1 million species described, is associated with developmental innovations like the holometaboly and the evolution from short to long germ-band embryogenesis. To unveil the mechanisms underlining these innovations, we compared gene expression during the ontogeny of two extreme neopterans, the cockroach Blattella germanica (polyneopteran, hemimetabolan and short germ-band species), and the fly Drosophila melanogaster (endopterygote, holometabolan and long germ-band species). Results revealed that genes associated with metamorphosis are predominantly expressed in late nymphal stages in B. germanica and in early-mid embryo in D. melanogaster. In B. germanica the maternal to zygotic transition (MZT) concentrates early in embryogenesis, when juvenile hormone factors are significantly expressed. In D. melanogaster, the MZT extends throughout embryogenesis, during which juvenile hormone factors appear unimportant. These differences possibly reflect broad trends in the evolution of development within neopterans, related to the germ-band type and the metamorphosis mode.

Project description:High temporal resolution RNAseq timecourse of mouse ES differentiation Investigations of transcriptional responses during developmental transitions typically use time courses with intervals that are not commensurate with the timescales of known biological processes. Moreover, such experiments typically focus on protein-coding transcripts, ignoring the important impact of long noncoding RNAs. We evaluated coding and noncoding expression dynamics at unprecedented temporal resolution (6-hourly) in differentiating mouse embryonic stem cells and report the effects of increased temporal resolution on the characterization of the underlying molecular processes.

Project description:Budding yeast grown under continuous, nutrient-limited conditions exhibit robust, highly periodic cycles in the form of respiratory bursts. Microarray studies reveal that over half of the yeast genome is expressed periodically during these metabolic cycles. Genes encoding proteins having a common function exhibit similar temporal expression patterns, and genes specifying functions associated with energy and metabolism tend to be expressed with exceptionally robust periodicity. Essential cellular and metabolic events occur in synchrony with the metabolic cycle, demonstrating that key processes in a simple eukaryotic cell are compartmentalized in time. This data set contains the raw affymetrix gene expression data over three successive metabolic cycles. 12 time intervals per cycle, ~25 min per time interval.

Project description:Next generation sequencing analysis of small RNA-seq and RNA-seq of successive time intervals during P. hawaiensis embryogenesis

Project description:In this study, we evaluated the effects of the post-mortem interval, defined as the number of days elapsed between the death of a donor and the isolation of hCECs, on the properties of hCECs. Using gene profiling, we compared the mRNA profiles of passage 1 hCECs (10 populations) cultivated in moculture with different post-mortem intervals and passage 2 hCECs (6 populations) with different post-mortem intervals from hTECs.

Project description:Temporal coordination of developmental programs is necessary for normal ontogeny, but the mechanism by which this is accomplished is poorly understood. We have previously shown that two components of the Mediator CDK8 module, CENTER CITY (CCT/MED12) and GRAND CENTRAL (GCT/MED13), are required for timing of pattern formation during embryogenesis in Arabidopsis. Here, we performed global gene expression analyses of wild-type, cct-1, and gct-2 seedlings (above-ground portions only) to help analyze their post-embryonic phenotypes. Our results suggest that MED12 and MED13 act as global regulators of developmental timing by fine-tuning expression of temporal regulatory genes.