Project description:In animals, egg activation triggers a cascade of posttranscriptional events that act on maternally synthesized RNAs. We show that, in Drosophila, the PAN GU (PNG) kinase sits near the top of this cascade, triggering translation of SMAUG (SMG), a multifunctional posttranscriptional regulator conserved from yeast to humans. Although PNG is required for cytoplasmic polyadenylation of smg mRNA, it regulates translation via mechanisms that are independent of its effects on the poly(A) tail. Analyses of mutants suggest that PNG relieves translational repression by PUMILIO (PUM) and one or more additional factors, which act in parallel through the smg mRNA's 3' untranslated region (UTR). Microarray-based gene expression profiling shows that SMG is a major regulator of maternal transcript destabilization. SMG-dependent mRNAs are enriched for gene ontology annotations for function in the cell cycle, suggesting a possible causal relationship between failure to eliminate these transcripts and the cell cycle defects in smg mutants. Keywords: Identification of Maternal mRNAs RNA was extracted from staged unfertilized eggs and stage 14 oocytes using a modification of the TRIzol (Invitrogen) method (Neal et al., 2003). Sample quality was evaluated by probing northern blots for known stable (rpA1) and unstable (Hsp83) transcripts. Total RNA was reverse transcribed as previously described (Neal et al., 2003), except that priming was carried out using random primers rather than oligo-dT in order not to bias the labeling toward mRNAs with long poly(A) tails. The fluorescently labeled cDNA probes were hybridized to 12Kv1 microarray slides obtained from the Canadian Drosophila Microarray Centre (http://www.flyarrays.com). These represent 10,500 distinct protein-coding genes, or 77% of the Drosophila protein-coding genome. Hybridization and scanning was also as previously described (Neal et al., 2003), using a PerkinElmer/GSI ScanArray 4000 scanner and the ScanArray software. The 16 bit TIFF image files were quantified using QuantArray Version 3 (PerkinElmer) using the adaptive quantification algorithm and analyzed using GeneTraffic Duo 3.2 (Iobion Informatics/Stratagene) after normalization to the known stable transcripts rpA1 and rp49. Of the 10,500 distinct protein-coding genes on the microarray, 9,257 were analyzed for maternal expression. The averages of all of the raw values for 21 hybridizations of wild-type stage 14 oocyte RNA (three replicates of seven experiments) were sorted from highest to lowest. Maternal expression was assessed at different levels in the list by scanning the Berkeley Drosophila Genome Project in situ database (http://www.fruitfly.org/cgi-bin/ex/insitu.pl). RNA from the genes at the top of the table is maternally loaded (90.4% of transcripts with an average raw intensity > 20,000 are maternal; n = 73), whereas RNA from genes at the bottom is absent from early embryos (only 8.2% of those with an average intensity of < 2,000 are maternal; n = 73). Hsp83 appeared near the top of the list (sixth out of 9,257). Transcripts with average values between 3,500 and 5,000 were mostly maternal (75%; n = 76). As the values decreased, there was a decreasing frequency of maternal transcripts (58.7% between 3,000 and 3,500, n = 172; 46.9% between 2,800 and 3,000, n = 160; 26.2% between 2,500 and 2,800, n = 80; 24.7% between 2,000 and 2,500, n = 81). Using a cutoff value of 3,000, we calculate that 55% of all protein-coding genes are represented in stage 14 oocytes

Project description:Microarray analysis of zygotic gene expression in 2-to-3 hour wild-type (wt) and smg mutant embryos. Expression is relative to mature, stage 14 oocytes, which contain the full maternal pool of mRNA. Strictly maternal genes that are not transcribed at the MZT contribute approximately 80% of transcripts in early embryos, and are not shown. Class I zygotic genes showed high levels of expression in 2-to-3 hour embryos. 142 of the 166 Class I genes were not expressed in smg mutants. The remaining zygotically expressed genes were also present in oocytes. These genes were divided into two classes, based on analysis of 4-to-6 hour old unfertilized eggs (4-6h unf), which are transcriptionally inactive. Class-II genes produce maternal transcripts that are stable in unfertilized eggs and show significantly increased expression in 2-to-3 hour post-fertilization embryos. 358 of 395 Class-II genes require SMAUG for zygotic expression. Class-III genes produce maternal transcripts that are degraded in unfertilized eggs and show significantly increased expression in 2-to-3 hour post-fertilization embryos. 65 of 408 Class-III genes require SMAUG for expression in 2-to-3 hour embryos.

Project description:Background: During the maternal-to-zygotic transition (MZT) vast changes in the embryonic transcriptome are produced by a combination of two processes: elimination of maternally provided mRNAs and synthesis of new transcripts from the zygotic genome. Previous genome-wide analyses of the MZT have been restricted to whole embryos. Here we report the first such analysis for primordial germ cells (PGCs), the progenitors of the germ-line stem cells. Results: We purified PGCs from Drosophila embryos, defined their proteome and transcriptome, and assessed the content, scale and dynamics of their MZT. Transcripts encoding proteins that implement particular types of biological functions group into nine distinct expression profiles, reflecting coordinate control at the transcriptional and posttranscriptional levels. mRNAs encoding germ-plasm components and cell-cell signaling molecules are rapidly degraded while new transcription produces mRNAs encoding the core transcriptional and protein synthetic machineries. The RNA-binding protein, Smaug, is essential for the PGC MZT, clearing transcripts encoding proteins that regulate stem cell behavior, transcriptional and posttranscriptional processes. Computational analyses suggest that Smaug and AU-rich element binding-proteins function independently to control transcript elimination. Conclusion: The scale of the MZT is similar in the soma and PGCs. However, the timing and content of their MZTs differ, reflecting the distinct developmental imperatives of these cell types. The PGC MZT is delayed relative to that in the soma, likely because relief of PGC-specific transcriptional silencing is required for zygotic genome activation as well as for efficient maternal transcript clearance. There are 26 samples in total, including 1-to-3 hour, 3-to-5 hour, 5-to-7 hour PGCs in wild type and smaug mutant flies and 1-to-3 hour somatic cells in wild type flies. Except for the 1-to-3 hour and 3-to-5 hour smaug mutant PGCs which have three replicates, all the other samples have four replicates.

Project description:Microarray analysis of zygotic gene expression in 2-to-3 hour wild-type (wt) and smg mutant embryos. Expression is relative to mature, stage 14 oocytes, which contain the full maternal pool of mRNA. Strictly maternal genes that are not transcribed at the MZT contribute approximately 80% of transcripts in early embryos, and are not shown. Class I zygotic genes showed high levels of expression in 2-to-3 hour embryos. 142 of the 166 Class I genes were not expressed in smg mutants. The remaining zygotically expressed genes were also present in oocytes. These genes were divided into two classes, based on analysis of 4-to-6 hour old unfertilized eggs (4-6h unf), which are transcriptionally inactive. Class-II genes produce maternal transcripts that are stable in unfertilized eggs and show significantly increased expression in 2-to-3 hour post-fertilization embryos. 358 of 395 Class-II genes require SMAUG for zygotic expression. Class-III genes produce maternal transcripts that are degraded in unfertilized eggs and show significantly increased expression in 2-to-3 hour post-fertilization embryos. 65 of 408 Class-III genes require SMAUG for expression in 2-to-3 hour embryos. mRNA was extracted from staged fertilized or unfertilized eggs, as well as stage 14 oocytes as described previously (Tadros et al., 2007a). To assay mRNA quality, known stable (rpA1) and unstable (Hsp83) transcripts were probed on Northern blots. Total RNA was then reverse transcribed with random primers (Tadros et al., 2007a) and labeled asÃ?described in the Indirect Labeling of Total RNA for Microarray Hybridization protocol at http://www.flyarrays.com. The fluorescently labeled cDNA probes were hybridized to 12Kv1 microarrays obtained from the Canadian Drosophila Microarray Centre (http://www.flyarrays.com; GEO platform accession number GPL1467: http://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GPL1467). Hybridization and scanning were performed using a PerkinElmer/GSI ScanArray 4000 scanner and the ScanArray software as previously described (Neal et al., 2003). The 16 bit TIFF image files were quantified using QuantArray Version 3 (PerkinElmer), using the adaptive quantification algorithm and analyzed using GeneTraffic Duo3.2 (Iobion Informatics/Stratagene). The 12Kv1 arrays were normalized using the rank invariant LOWESS extrapolation method (Schadt et al., 2001).

Project description:In animal embryos the maternal-to-zygotic transition (MZT) hands developmental control from maternal to zygotic gene products. We show that the maternal proteome represents over half of the protein coding capacity of the Drosophila melanogaster genome and that 2% of this proteome is rapidly degraded during the MZT. Cleared proteins include the post-transcriptional repressors Cup, Trailer hitch (TRAL), Maternal expression at 31B (ME31B), and Smaug (SMG). While the ubiquitin-proteasome system is necessary for clearance of all four repressors, distinct E3 ligase complexes target them: the C-terminal to Lis1 Homology (CTLH) complex targets Cup, TRAL and ME31B for degradation early in the MZT; the Skp/Cullin/F-box-containing (SCF) complex targets SMG at the end of the MZT. Deleting the C-terminal 233 amino acids of SMG make it immune to degradation. We show that artificially persistent SMG downregulates the zygotic re-expression of mRNAs whose maternal contribution is cleared by SMG. Thus, clearance of SMG permits an orderly MZT.

Project description:In animal embryos the maternal-to-zygotic transition (MZT) hands developmental control from maternal to zygotic gene products. We show that the maternal proteome represents over half of the protein coding capacity of the Drosophila melanogaster genome and that 2% of this proteome is rapidly degraded during the MZT. Cleared proteins include the post-transcriptional repressors Cup, Trailer hitch (TRAL), Maternal expression at 31B (ME31B), and Smaug (SMG). While the ubiquitin-proteasome system is necessary for clearance of all four repressors, distinct E3 ligase complexes target them: the C-terminal to Lis1 Homology (CTLH) complex targets Cup, TRAL and ME31B for degradation early in the MZT; the Skp/Cullin/F-box-containing (SCF) complex targets SMG at the end of the MZT. Deleting the C-terminal 233 amino acids of SMG makes the protein immune to degradation. We show that artificially persistent SMG downregulates the zygotic re-expression of mRNAs whose maternal contribution is cleared by SMG. Thus, clearance of SMG permits an orderly MZT.

Project description:Background: Metazoan embryos undergo a maternal-to-zygotic transition (MZT) during which a subset of maternal gene products is eliminated and the zygotic genome becomes transcriptionally active. RNA-binding proteins (RBPs) and the microRNA-induced silencing complex (miRISC) – of which Argonaute 1 (AGO1) is a key component in Drosophila – target maternal mRNAs for degradation. The Drosophila Smaug, Brain tumor (BRAT) and Pumilio (PUM) RBPs direct the degradation of maternal mRNAs. Here we elucidate Smaug’s roles in regulation of miRNAs and miRISC during the MZT. Results: By global analysis of small RNAs at several stages during the MZT, we show that the vast majority of all miRNA species encoded by the Drosophila genome (85%) are expressed during the MZT. Whereas a subset of these miRNAs is loaded into oocytes by the mother and stays at constant levels during the MZT, dozens of miRNA species are either newly synthesized or re-expressed in the early embryo. Loss of Smaug has a profound effect on miRNAs but little effect on piRNAs or siRNAs. Smaug is required for production of new miRNAs during the MZT; Smaug-bound AGO1 reflects the constellation and abundance of the miRNAs present in early embryos; and Smaug is required for the increase in AGO1 protein levels that occurs during the MZT. As a consequence of low miRISC activity in smaug mutants, maternal mRNAs that are normally targeted for degradation by zygotic miRNAs fail to be cleared. BRAT and PUM share target mRNAs with miRISC during the MZT while the miR-309 miRNA family coregulates targets of BRAT but not PUM. Conclusions: Smaug controls the MZT through direct targeting of a subset of maternal mRNAs for degradation and, indirectly, through production and function of miRNAs and miRISC, which control clearance of a distinct subset of maternal mRNAs. BRAT and/or PUM function together with miRISC during the latter process. With respect to miRISC-dependent transcript degradation, Smaug is required (1) for the synthesis of miRNAs, (2) for synthesis and stabilization of AGO1, and (3) for action of AGO1 in association with its bound miRNAs. In smaug mutants a large number of maternal mRNAs persist and the MZT fails.

Project description:Background: Metazoan embryos undergo a maternal-to-zygotic transition (MZT) during which a subset of maternal gene products is eliminated and the zygotic genome becomes transcriptionally active. RNA-binding proteins (RBPs) and the microRNA-induced silencing complex (miRISC) – of which Argonaute 1 (AGO1) is a key component in Drosophila – target maternal mRNAs for degradation. The Drosophila Smaug, Brain tumor (BRAT) and Pumilio (PUM) RBPs direct the degradation of maternal mRNAs. Here we elucidate Smaug’s roles in regulation of miRNAs and miRISC during the MZT. Results: By global analysis of small RNAs at several stages during the MZT, we show that the vast majority of all miRNA species encoded by the Drosophila genome (85%) are expressed during the MZT. Whereas a subset of these miRNAs is loaded into oocytes by the mother and stays at constant levels during the MZT, dozens of miRNA species are either newly synthesized or re-expressed in the early embryo. Loss of Smaug has a profound effect on miRNAs but little effect on piRNAs or siRNAs. Smaug is required for production of new miRNAs during the MZT; Smaug-bound AGO1 reflects the constellation and abundance of the miRNAs present in early embryos; and Smaug is required for the increase in AGO1 protein levels that occurs during the MZT. As a consequence of low miRISC activity in smaug mutants, maternal mRNAs that are normally targeted for degradation by zygotic miRNAs fail to be cleared. BRAT and PUM share target mRNAs with miRISC during the MZT while the miR-309 miRNA family coregulates targets of BRAT but not PUM. Conclusions: Smaug controls the MZT through direct targeting of a subset of maternal mRNAs for degradation and, indirectly, through production and function of miRNAs and miRISC, which control clearance of a distinct subset of maternal mRNAs. BRAT and/or PUM function together with miRISC during the latter process. With respect to miRISC-dependent transcript degradation, Smaug is required (1) for the synthesis of miRNAs, (2) for synthesis and stabilization of AGO1, and (3) for action of AGO1 in association with its bound miRNAs. In smaug mutants a large number of maternal mRNAs persist and the MZT fails. Examination of miRNA expresssion at different time points in wild type and smuag mutant early embryos .

Project description:Background: During the maternal-to-zygotic transition (MZT) vast changes in the embryonic transcriptome are produced by a combination of two processes: elimination of maternally provided mRNAs and synthesis of new transcripts from the zygotic genome. Previous genome-wide analyses of the MZT have been restricted to whole embryos. Here we report the first such analysis for primordial germ cells (PGCs), the progenitors of the germ-line stem cells. Results: We purified PGCs from Drosophila embryos, defined their proteome and transcriptome, and assessed the content, scale and dynamics of their MZT. Transcripts encoding proteins that implement particular types of biological functions group into nine distinct expression profiles, reflecting coordinate control at the transcriptional and posttranscriptional levels. mRNAs encoding germ-plasm components and cell-cell signaling molecules are rapidly degraded while new transcription produces mRNAs encoding the core transcriptional and protein synthetic machineries. The RNA-binding protein, Smaug, is essential for the PGC MZT, clearing transcripts encoding proteins that regulate stem cell behavior, transcriptional and posttranscriptional processes. Computational analyses suggest that Smaug and AU-rich element binding-proteins function independently to control transcript elimination. Conclusion: The scale of the MZT is similar in the soma and PGCs. However, the timing and content of their MZTs differ, reflecting the distinct developmental imperatives of these cell types. The PGC MZT is delayed relative to that in the soma, likely because relief of PGC-specific transcriptional silencing is required for zygotic genome activation as well as for efficient maternal transcript clearance.

Project description:The behavior of 410 miR-309-dependent maternal mRNAs (from Bushati et al., 2008) in embryos from wild type and smg-mutant females relative to wild-type stage 14 oocyte reference RNA. All are unstable in wild-type while almost 85% are stabilized in smg mutants