Your search keyword '"Simonelig, M."' showing total 66 results

51. Maternal mRNA deadenylation and decay by the piRNA pathway in the early Drosophila embryo.

Author

Rouget C, Papin C, Boureux A, Meunier AC, Franco B, Robine N, Lai EC, Pelisson A, and Simonelig M

Subjects

3' Untranslated Regions genetics, Animals, Argonaute Proteins, Cytoplasm genetics, Cytoplasm metabolism, DNA Transposable Elements genetics, Drosophila Proteins genetics, Drosophila Proteins metabolism, Drosophila melanogaster cytology, Embryo, Nonmammalian cytology, Embryo, Nonmammalian embryology, Embryo, Nonmammalian metabolism, Female, Mothers, Peptide Initiation Factors genetics, Peptide Initiation Factors metabolism, RNA, Messenger genetics, RNA, Small Interfering metabolism, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism, Repressor Proteins genetics, Repressor Proteins metabolism, Ribonucleases genetics, Ribonucleases metabolism, Zygote metabolism, Drosophila melanogaster embryology, Drosophila melanogaster genetics, Gene Expression Regulation, Developmental, Polyadenylation genetics, RNA Stability, RNA, Messenger metabolism, RNA, Small Interfering genetics

Abstract

Piwi-associated RNAs (piRNAs), a specific class of 24- to 30-nucleotide-long RNAs produced by the Piwi-type of Argonaute proteins, have a specific germline function in repressing transposable elements. This repression is thought to involve heterochromatin formation and transcriptional and post-transcriptional silencing. The piRNA pathway has other essential functions in germline stem cell maintenance and in maintaining germline DNA integrity. Here we uncover an unexpected function of the piRNA pathway in the decay of maternal messenger RNAs and in translational repression in the early embryo. A subset of maternal mRNAs is degraded in the embryo at the maternal-to-zygotic transition. In Drosophila, maternal mRNA degradation depends on the RNA-binding protein Smaug and the deadenylase CCR4, as well as the zygotic expression of a microRNA cluster. Using mRNA encoding the embryonic posterior morphogen Nanos (Nos) as a paradigm to study maternal mRNA decay, we found that CCR4-mediated deadenylation of nos depends on components of the piRNA pathway including piRNAs complementary to a specific region in the nos 3' untranslated region. Reduced deadenylation when piRNA-induced regulation is impaired correlates with nos mRNA stabilization and translational derepression in the embryo, resulting in head development defects. Aubergine, one of the Argonaute proteins in the piRNA pathway, is present in a complex with Smaug, CCR4, nos mRNA and piRNAs that target the nos 3' untranslated region, in the bulk of the embryo. We propose that piRNAs and their associated proteins act together with Smaug to recruit the CCR4 deadenylation complex to specific mRNAs, thus promoting their decay. Because the piRNAs involved in this regulation are produced from transposable elements, this identifies a direct developmental function for transposable elements in the regulation of gene expression.

Published

2010

52. Subunits of the Drosophila CCR4-NOT complex and their roles in mRNA deadenylation.

Author

Temme C, Zhang L, Kremmer E, Ihling C, Chartier A, Sinz A, Simonelig M, and Wahle E

Subjects

Adenosine Monophosphate metabolism, Animals, Cell Line, Drosophila Proteins analysis, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Proteome analysis, RNA, Messenger metabolism, Retinoblastoma-Binding Protein 4 metabolism, Ribonucleases chemistry, Drosophila melanogaster enzymology, Ribonucleases metabolism

Abstract

The CCR4-NOT complex is the main enzyme catalyzing the deadenylation of mRNA. We have investigated the composition of this complex in Drosophila melanogaster by immunoprecipitation with a monoclonal antibody directed against NOT1. The CCR4, CAF1 (=POP2), NOT1, NOT2, NOT3, and CAF40 subunits were associated in a stable complex, but NOT4 was not. Factors known to be involved in mRNA regulation were prominent among the other proteins coprecipitated with the CCR4-NOT complex, as analyzed by mass spectrometry. The complex was localized mostly in the cytoplasm but did not appear to be a major component of P bodies. Of the known CCR4 paralogs, Nocturnin was found associated with the subunits of the CCR4-NOT complex, whereas Angel and 3635 were not. RNAi experiments in Schneider cells showed that CAF1, NOT1, NOT2, and NOT3 are required for bulk poly(A) shortening and hsp70 mRNA deadenylation, but knock-down of CCR4, CAF40, and NOT4 did not affect these processes. Overexpression of catalytically dead CAF1 had a dominant-negative effect on mRNA decay. In contrast, overexpression of inactive CCR4 had no effect. We conclude that CAF1 is the major catalytically important subunit of the CCR4-NOT complex in Drosophila Schneider cells. Nocturnin may also be involved in mRNA deadenylation, whereas there is no evidence for a similar role of Angel and 3635.

Published

2010

53. Prevention of oculopharyngeal muscular dystrophy by muscular expression of Llama single-chain intrabodies in vivo.

Author

Chartier A, Raz V, Sterrenburg E, Verrips CT, van der Maarel SM, and Simonelig M

Subjects

Animals, Antibodies, Monoclonal metabolism, Antibodies, Monoclonal therapeutic use, Camelids, New World, Female, Genetic Therapy, Humans, Immunotherapy, Male, Muscle, Skeletal metabolism, Muscular Dystrophy, Oculopharyngeal genetics, Muscular Dystrophy, Oculopharyngeal metabolism, Muscular Dystrophy, Oculopharyngeal prevention & control, Poly(A)-Binding Protein II metabolism, Protein Transport, Antibodies, Monoclonal genetics, Antibodies, Monoclonal immunology, Disease Models, Animal, Drosophila genetics, Drosophila metabolism, Muscular Dystrophy, Oculopharyngeal therapy, Poly(A)-Binding Protein II immunology

Abstract

Oculopharyngeal muscular dystrophy (OPMD) is a late onset disorder characterized by progressive weakening of specific muscles. It is caused by short expansions of the N-terminal polyalanine tract in the poly(A) binding protein nuclear 1 (PABPN1), and it belongs to the group of protein aggregation diseases, such as Huntington's, Parkinson's and Alzheimer diseases. Mutant PABPN1 forms nuclear aggregates in diseased muscles in both patients and animal models. Intrabodies are antibodies that are modified to be expressed intracellularly and target specific antigens in subcellular locations. They are commonly generated by artificially linking the variable domains of antibody heavy and light chains. However, natural single-chain antibodies are produced in Camelids and, when engineered, combined the advantages of being single-chain, small sized and very stable. Here, we determine the in vivo efficiency of Llama intrabodies against PABPN1, using the established Drosophila model of OPMD. Among six anti-PABPN1 intrabodies expressed in muscle nuclei, we identify one as a strong suppressor of OPMD muscle degeneration in Drosophila, leading to nearly complete rescue. Expression of this intrabody affects PABPN1 aggregation and restores muscle gene expression. This approach promotes the identification of intrabodies with high therapeutic value and highlights the potential of natural single-chain intrabodies in treating protein aggregation diseases.

Published

2009

54. PAP- and GLD-2-type poly(A) polymerases are required sequentially in cytoplasmic polyadenylation and oogenesis in Drosophila.

Author

Benoit P, Papin C, Kwak JE, Wickens M, and Simonelig M

Subjects

Animals, Blotting, Western, Cdc20 Proteins, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, Cytoplasm metabolism, Drosophila metabolism, Drosophila Proteins metabolism, Eye Proteins metabolism, Female, Gene Expression Regulation, Developmental, Immunoprecipitation, Meiosis genetics, Metaphase genetics, Polynucleotide Adenylyltransferase metabolism, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism, Drosophila genetics, Drosophila Proteins genetics, Eye Proteins genetics, Oogenesis genetics, Polyadenylation genetics, Polynucleotide Adenylyltransferase genetics

Abstract

Cytoplasmic polyadenylation has an essential role in activating maternal mRNA translation during early development. In vertebrates, the reaction requires CPEB, an RNA-binding protein and the poly(A) polymerase GLD-2. GLD-2-type poly(A) polymerases form a family clearly distinguishable from canonical poly(A) polymerases (PAPs). In Drosophila, canonical PAP is involved in cytoplasmic polyadenylation with Orb, the Drosophila CPEB, during mid-oogenesis. We show that the female germline GLD-2 is encoded by wispy. Wispy acts as a poly(A) polymerase in a tethering assay and in vivo for cytoplasmic polyadenylation of specific mRNA targets during late oogenesis and early embryogenesis. wispy function is required at the final stage of oogenesis for metaphase of meiosis I arrest and for progression beyond this stage. By contrast, canonical PAP acts with Orb for the earliest steps of oogenesis. Both Wispy and PAP interact with Orb genetically and physically in an ovarian complex. We conclude that two distinct poly(A) polymerases have a role in cytoplasmic polyadenylation in the female germline, each of them being specifically required for different steps of oogenesis.

Published

2008

55. Bicaudal-C recruits CCR4-NOT deadenylase to target mRNAs and regulates oogenesis, cytoskeletal organization, and its own expression.

Author

Chicoine J, Benoit P, Gamberi C, Paliouras M, Simonelig M, and Lasko P

Subjects

5' Untranslated Regions, Animals, Biological Transport, Active, Body Patterning, Cytoplasm metabolism, Drosophila embryology, Drosophila Proteins genetics, Female, Mutation, Oogenesis, Poly A metabolism, RNA, Messenger genetics, RNA-Binding Proteins genetics, Ribonucleases genetics, Cytoskeleton physiology, Drosophila physiology, Drosophila Proteins physiology, RNA, Messenger physiology, RNA-Binding Proteins physiology, Ribonucleases physiology

Abstract

Bicaudal-C (Bic-C) encodes an RNA-binding protein required maternally for patterning the Drosophila embryo. We identified a set of mRNAs that associate with Bic-C in ovarian ribonucleoprotein complexes. These mRNAs are enriched for mRNAs that function in oogenesis and in cytoskeletal regulation, and include Bic-C RNA itself. Bic-C binds specific segments of the Bic-C 5' untranslated region and negatively regulates its own expression by binding directly to NOT3/5, a component of the CCR4 core deadenylase complex, thereby promoting deadenylation. Bic-C overexpression induces premature cytoplasmic-streaming, a posterior-group phenotype, defects in Oskar and Kinesin heavy chain:betaGal localization as well as dorsal-appendage defects. These phenotypes are largely reciprocal to those of Bic-C mutants, and they affect cellular processes that Bic-C-associated mRNAs are known, or predicted, to regulate. We conclude that Bic-C regulates expression of specific germline mRNAs by controlling their poly(A)-tail length.

Published

2007

56. Oskar allows nanos mRNA translation in Drosophila embryos by preventing its deadenylation by Smaug/CCR4.

Author

Zaessinger S, Busseau I, and Simonelig M

Subjects

Animals, Blotting, Western, DNA Primers, Drosophila metabolism, Immunoprecipitation, In Situ Hybridization, Repressor Proteins metabolism, Ribonucleases metabolism, Body Patterning physiology, Drosophila embryology, Drosophila Proteins metabolism, Gene Expression Regulation, Developmental, Protein Biosynthesis physiology, RNA, Messenger metabolism, RNA-Binding Proteins metabolism

Abstract

Anteroposterior patterning of the Drosophila embryo depends on a gradient of Nanos protein arising from the posterior pole. This gradient results from both nanos mRNA translational repression in the bulk of the embryo and translational activation of nanos mRNA localized at the posterior pole. Two mechanisms of nanos translational repression have been described, at the initiation step and after this step. Here we identify a novel level of nanos translational control. We show that the Smaug protein bound to the nanos 3' UTR recruits the deadenylation complex CCR4-NOT, leading to rapid deadenylation and subsequent decay of nanos mRNA. Inhibition of deadenylation causes stabilization of nanos mRNA, ectopic synthesis of Nanos protein and head defects. Therefore, deadenylation is essential for both translational repression and decay of nanos mRNA. We further propose a mechanism for translational activation at the posterior pole. Translation of nanos mRNA at the posterior pole depends on oskar function. We show that Oskar prevents the rapid deadenylation of nanos mRNA by precluding its binding to Smaug, thus leading to its stabilization and translation. This study provides insights into molecular mechanisms of regulated deadenylation by specific proteins and demonstrates its importance in development.

Published

2006

57. A Drosophila model of oculopharyngeal muscular dystrophy reveals intrinsic toxicity of PABPN1.

Author

Chartier A, Benoit B, and Simonelig M

Subjects

Animals, Animals, Genetically Modified, Disease Models, Animal, Drosophila melanogaster anatomy & histology, Humans, Molecular Chaperones metabolism, Muscle, Skeletal anatomy & histology, Muscle, Skeletal metabolism, Muscle, Skeletal pathology, Phenotype, Poly(A)-Binding Protein I genetics, Tumor Suppressor Protein p53 metabolism, Wings, Animal anatomy & histology, Drosophila melanogaster physiology, Muscular Dystrophy, Oculopharyngeal genetics, Muscular Dystrophy, Oculopharyngeal pathology, Muscular Dystrophy, Oculopharyngeal physiopathology, Poly(A)-Binding Protein I metabolism

Abstract

Oculopharyngeal muscular dystrophy (OPMD) is an adult-onset syndrome characterized by progressive degeneration of particular muscles. OPMD is caused by short GCG repeat expansions within the gene encoding the nuclear poly(A)-binding protein 1 (PABPN1) that extend an N-terminal polyalanine tract in the protein. Mutant PABPN1 aggregates as nuclear inclusions in OMPD patient muscles. We have created a Drosophila model of OPMD that recapitulates the features of the human disorder: progressive muscle degeneration, with muscle defects proportional to the number of alanines in the tract, and formation of PABPN1 nuclear inclusions. Strikingly, the polyalanine tract is not absolutely required for muscle degeneration, whereas another domain of PABPN1, the RNA-binding domain and its function in RNA binding are required. This demonstrates that OPMD does not result from polyalanine toxicity, but from an intrinsic property of PABPN1. We also identify several suppressors of the OPMD phenotype. This establishes our OPMD Drosophila model as a powerful in vivo test to understand the disease process and develop novel therapeutic strategies.

Published

2006

58. An essential cytoplasmic function for the nuclear poly(A) binding protein, PABP2, in poly(A) tail length control and early development in Drosophila.

Author

Benoit B, Mitou G, Chartier A, Temme C, Zaessinger S, Wahle E, Busseau I, and Simonelig M

Subjects

Amino Acid Sequence, Animals, Body Patterning, Cell Cycle physiology, Cyclin B genetics, Cyclin B metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism, Embryo, Nonmammalian anatomy & histology, Embryo, Nonmammalian physiology, Female, Male, Molecular Sequence Data, Oocytes physiology, Poly(A)-Binding Protein II genetics, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Ribonucleases genetics, Ribonucleases metabolism, Drosophila melanogaster embryology, Gene Expression Regulation, Developmental, Poly(A)-Binding Protein II metabolism, RNA, Messenger metabolism

Abstract

Translational control of maternal mRNA through regulation of poly(A) tail length is crucial during early development. The nuclear poly(A) binding protein, PABP2, was identified biochemically from its role in nuclear polyadenylation. Here, we analyze the in vivo function of PABP2 in Drosophila. PABP2 is required in vivo for polyadenylation, and Pabp2 function, including poly(A) polymerase stimulation, is essential for viability. We also demonstrate an unanticipated cytoplasmic function for PABP2 during early development. In contrast to its role in nuclear polyadenylation, cytoplasmic PABP2 acts to shorten the poly(A) tails of specific mRNAs. PABP2, together with the deadenylase CCR4, regulates the poly(A) tails of oskar and cyclin B mRNAs, both of which are also controlled by cytoplasmic polyadenylation. Both Cyclin B protein levels and embryonic development depend upon this regulation. These results identify a regulator of maternal mRNA poly(A) tail length and highlight the importance of this mode of translational control.

Published

2005

59. A complex containing the CCR4 and CAF1 proteins is involved in mRNA deadenylation in Drosophila.

Author

Temme C, Zaessinger S, Meyer S, Simonelig M, and Wahle E

Subjects

Amino Acid Sequence, Animals, Catalytic Domain, Cells, Cultured, Chromosomal Proteins, Non-Histone genetics, Chromosomal Proteins, Non-Histone metabolism, Conserved Sequence, Cytoplasm metabolism, Drosophila cytology, HSP70 Heat-Shock Proteins metabolism, Molecular Chaperones genetics, Molecular Chaperones metabolism, Molecular Sequence Data, Mutation, Protein Processing, Post-Translational, Protein Structure, Tertiary, RNA Interference, Retinoblastoma-Binding Protein 4, Ribonucleases chemistry, Ribonucleases metabolism, Saccharomyces cerevisiae Proteins chemistry, Sequence Homology, Amino Acid, Drosophila metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism, RNA, Messenger metabolism, Ribonucleases genetics, Saccharomyces cerevisiae Proteins genetics

Abstract

The CCR4-NOT complex is the major enzyme catalyzing mRNA deadenylation in Saccharomyces cerevisiae. We have identified homologs for almost all subunits of this complex in the Drosophila genome. Biochemical fractionation showed that the two likely catalytic subunits, CCR4 and CAF1, were associated with each other and with a poly(A)-specific 3' exonuclease activity. In Drosophila, the CCR4 and CAF1 proteins were ubiquitously expressed and present in cytoplasmic foci. Individual knock-down of several potential subunits of the Drosophila CCR4-NOT complex by RNAi in tissue culture cells led to a lengthening of bulk mRNA poly(A) tails. Knock-down of two individual subunits also interfered with the rapid deadenylation of Hsp70 mRNA during recovery from heat shock. Similarly, ccr4 mutant flies had elongated bulk poly(A) and a defect in Hsp70 mRNA deadenylation. A minor increase in bulk poly(A) tail length was also observed in Rga mutant flies, which are affected in the NOT2 subunit. The data show that the CCR4-NOT complex is conserved in Drosophila melanogaster and plays a role in general and regulated mRNA deadenylation.

Published

2004

60. Control of poly(A) polymerase level is essential to cytoplasmic polyadenylation and early development in Drosophila.

Author

Juge F, Zaessinger S, Temme C, Wahle E, and Simonelig M

Subjects

Animals, Cell Nucleus metabolism, Drosophila embryology, Drosophila Proteins metabolism, Gene Expression Profiling, Polynucleotide Adenylyltransferase genetics, RNA Precursors metabolism, RNA-Binding Proteins metabolism, Cytoplasm metabolism, Drosophila physiology, Polyadenylation physiology, Polynucleotide Adenylyltransferase metabolism

Abstract

Poly(A) polymerase (PAP) has a role in two processes, polyadenylation of mRNA precursors in the nucleus and translational control of certain mRNAs by cytoplasmic elongation of their poly(A) tails, particularly during early development. It was found recently that at least three different PAP genes exist in mammals, encoding several PAP isoforms. The in vivo specificity of function of each PAP isoform currently is unknown. Here, we analyse PAP function in Drosophila: We show that a single PAP isoform exists in Drosophila that is encoded by the hiiragi gene. This single Drosophila PAP is active in specific polyadenylation in vitro and is involved in both nuclear and cytoplasmic polyadenylation in vivo. Therefore, the same PAP can be responsible for both processes. In addition, in vivo overexpression of PAP does not affect poly(A) tail length during nuclear polyadenylation, but leads to a dramatic elongation of poly(A) tails and a loss of specificity during cytoplasmic polyadenylation, resulting in embryonic lethality. This demonstrates that regulation of the PAP level is essential for controlled cytoplasmic polyadenylation and early development.

Published

2002

61. Chimeric human CstF-77/Drosophila Suppressor of forked proteins rescue suppressor of forked mutant lethality and mRNA 3' end processing in Drosophila.

Author

Benoit B, Juge F, Iral F, Audibert A, and Simonelig M

Subjects

Amino Acid Sequence, Animals, Base Sequence, Binding Sites, DNA, Complementary, Drosophila melanogaster, Humans, Insect Proteins genetics, Molecular Sequence Data, Mutagenesis, Poly A, RNA-Binding Proteins genetics, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins physiology, Sequence Homology, Amino Acid, mRNA Cleavage and Polyadenylation Factors, Drosophila Proteins, Insect Proteins physiology, Nuclear Proteins, RNA Precursors, RNA Processing, Post-Transcriptional, RNA-Binding Proteins physiology

Abstract

The Suppressor of forked [Su(f)] protein is the Drosophila homologue of CstF-77, a subunit of human cleavage stimulation factor (CstF) that is required for the first step of the mRNA 3' end processing reaction in vitro. We have addressed directly the role of su(f) in the mRNA 3' end processing reaction in vivo. We show that su(f) is required for the cleavage of pre-mRNA during mRNA 3' end formation. Analysis of the functional complementation between Su(f) and CstF-77 shows that most of the Drosophila protein (85%) can be exchanged for the human protein to produce chimeric CstF-77/Su(f) proteins that rescue lethality and cleavage defect during mRNA 3' end formation in su(f) mutants. Interestingly, we show that a domain in human CstF-77 is limiting for the rescue and that this domain is not able to reproduce protein interactions with the CstF subunits of Drosophila. We also show that chimeric CstF-77/Su(f) proteins that rescue lethality of su(f) mutants cannot restore utilization of a regulated poly(A) site in Drosophila. Taken together, these results demonstrate that CstF-77 and Su(f) have the same function in mRNA 3' end formation in vivo, but that these two proteins are not interchangeable for regulation of poly(A) site utilization.

Published

2002

62. Tissue-specific autoregulation of Drosophila suppressor of forked by alternative poly(A) site utilization leads to accumulation of the suppressor of forked protein in mitotically active cells.

Author

Juge F, Audibert A, Benoit B, and Simonelig M

Subjects

Animals, Animals, Genetically Modified, Drosophila melanogaster physiology, Gene Expression Regulation, Humans, Introns, Larva, Malpighian Tubules physiology, Mitosis, Organ Specificity, Reverse Transcriptase Polymerase Chain Reaction, Wings, Animal physiology, beta-Glucosidase genetics, Drosophila Proteins, Drosophila melanogaster genetics, Insect Proteins metabolism, Nuclear Proteins, Poly A metabolism, RNA, Messenger genetics, Transcription, Genetic

Abstract

The Suppressor of forked protein is the Drosophila homolog of the 77K subunit of human cleavage stimulation factor, a complex required for the first step of the mRNA 3'-end-processing reaction. We have shown previously that wild-type su(f) function is required for the accumulation of a truncated su(f) transcript polyadenylated in intron 4 of the gene. This led us to propose a model in which the Su(f) protein would negatively regulate its own accumulation by stimulating 3'-end formation of this truncated su(f) RNA. In this article, we demonstrate this model and show that su(f) autoregulation is tissue specific. The Su(f) protein accumulates at a high level in dividing tissues, but not in nondividing tissues. We show that this distribution of the Su(f) protein results from stimulation by Su(f) of the tissue-specific utilization of the su(f) intronic poly(A) site, leading to the accumulation of the truncated su(f) transcript in nondividing tissues. Utilization of this intronic poly(A) site is affected in a su(f) mutant and restored in the mutant with a transgene encoding wild-type Su(f) protein. These data provide an in vivo example of cell-type-specific regulation of a protein level by poly(A) site choice, and confirm the role of Su(f) in regulation of poly(A) site utilization.

Published

2000

63. Autoregulation at the level of mRNA 3' end formation of the suppressor of forked gene of Drosophila melanogaster is conserved in Drosophila virilis.

Author

Audibert A and Simonelig M

Subjects

Amino Acid Sequence, Animals, Animals, Genetically Modified, Base Sequence, Conserved Sequence, Exons, Fungal Proteins chemistry, Fungal Proteins genetics, Homeostasis, Humans, Insect Proteins chemistry, Introns, Macromolecular Substances, Molecular Sequence Data, RNA-Binding Proteins chemistry, RNA-Binding Proteins genetics, Saccharomyces cerevisiae genetics, Sequence Alignment, Sequence Homology, Amino Acid, Sequence Homology, Nucleic Acid, mRNA Cleavage and Polyadenylation Factors, Drosophila genetics, Drosophila Proteins, Drosophila melanogaster genetics, Gene Expression Regulation, Insect Proteins genetics, Nuclear Proteins, RNA, Messenger genetics, Saccharomyces cerevisiae Proteins, Transcription, Genetic

Abstract

The Drosophila melanogaster Suppressor of forked [Su(f)] protein shares homology with the yeast RNA14 protein and the 77-kDa subunit of human cleavage stimulation factor, which are proteins involved in mRNA 3' end formation. This suggests a role for Su(f) in mRNA 3' end formation in Drosophila. The su(f) gene produces three transcripts; two of them are polyadenylated at the end of the transcription unit, and one is a truncated transcript, polyadenylated in intron 4. Using temperature-sensitive su(f) mutants, we show that accumulation of the truncated transcript requires wild-type Su(f) protein. This suggests that the Su(f) protein autoregulates negatively its accumulation by stimulating 3' end formation of the truncated su(f) RNA. Cloning of su(f) from Drosophila virilis and analysis of its RNA profile suggest that su(f) autoregulation is conserved in this species. Sequence comparison between su(f) from both species allows us to point out three conserved regions in intron 4 downstream of the truncated RNA poly(A) site. These conserved regions include the GU-rich downstream sequence involved in poly(A) site definition. Using transgenes truncated within intron 4, we show that sequence up to the conserved GU-rich domain is sufficient for production of the truncated RNA and for regulation of this production by su(f). Our results indicate a role of su(f) in the regulation of poly(A) site utilization and an important role of the GU-rich sequence for this regulation to occur.

Published

1998

64. Detection of mitotic spindles in third-instar imaginal discs of Drosophila melanogaster.

Author

Audibert A, Debec A, and Simonelig M

Subjects

Animals, Drosophila melanogaster embryology, Larva genetics, Microscopy, Confocal, Mitosis, Spindle Apparatus immunology, Drosophila melanogaster anatomy & histology, Drosophila melanogaster genetics, Fluorescent Antibody Technique, Direct methods, Spindle Apparatus genetics

Published

1996

65. Interallelic complementation at the suppressor of forked locus of Drosophila reveals complementation between suppressor of forked proteins mutated in different regions.

Author

Simonelig M, Elliott K, Mitchelson A, and O'Hare K

Subjects

Alleles, Amino Acid Sequence, Animals, Base Sequence, Chromosome Mapping, DNA, DNA-Binding Proteins genetics, Genetic Complementation Test, Molecular Sequence Data, Mutation, Transformation, Genetic, Drosophila Proteins, Drosophila melanogaster genetics, Nuclear Proteins, Proteins genetics

Abstract

The Su(f) protein of Drosophila melanogaster shares extensive homologies with proteins from yeast (RNA14) and man (77 kD subunit of cleavage stimulation factor) that are required for 3' end processing of mRNA. These homologies suggest that su(f) is involved in mRNA 3' end formation and that some aspects of this process are conserved throughout eukaryotes. We have investigated the genetic and molecular complexity of the su(f) locus. The su(f) gene is transcribed to produce three RNAs and could encode two proteins. Using constructs that contain different parts of the locus, we show that only the larger predicted gene product of 84 kD is required for the wild-type function of su(f). Some lethal alleles of su(f) complement to produce viable combinations. The structures of complementing and noncomplementing su(f) alleles indicate that 84-kD Su(f) proteins mutated in different domains can act in combination for partial su(f) function. Our results suggest protein-protein interaction between or within wild-type Su(f) molecules.

Published

1996

66. Drosophila P element: transposition, regulation and evolution.

Author

Coen D, Lemaitre B, Delattre M, Quesneville H, Ronsseray S, Simonelig M, Higuet D, Lehmann M, Montchamp C, and Nouaud D

Subjects

Animals, Crosses, Genetic, DNA Repair, Female, Male, Models, Genetic, Phylogeny, Transcription, Genetic, Biological Evolution, DNA Transposable Elements, Drosophila melanogaster genetics, Gene Expression Regulation

Published

1994