Regulation of Prp43-mediated disassembly of spliceosomes by its cofactors Ntr1 and Ntr2.

The DEAH-box NTPase Prp43 disassembles spliceosomes in co-operation with the cofactors Ntr1/Spp382 and Ntr2, forming the NTR complex. How Prp43 is regulated by its cofactors to discard selectively only intron-lariat spliceosomes (ILS) and defective spliceosomes and to prevent disassembly of earlier and properly assembled/wild-type spliceosomes remains unclear. First, we show that Ntr1's G-patch motif (Ntr1GP) can be replaced by the GP motif of Pfa1/Sqs1, a Prp43's cofactor in ribosome biogenesis, demonstrating that the specific function of Ntr1GP is to activate Prp43 for spliceosome disassembly and not to guide Prp43 to its binding site in the spliceosome. Furthermore, we show that Ntr1's C-terminal domain (CTD) plays a safeguarding role by preventing Prp43 from disrupting wild-type spliceosomes other than the ILS. Ntr1 and Ntr2 can also discriminate between wild-type and defective spliceosomes. In both type of spliceosomes, Ntr1-CTD impedes Prp43-mediated disassembly while the Ntr1GP promotes disassembly. Intriguingly, Ntr2 plays a specific role in defective spliceosomes, likely by stabilizing Ntr1 and allowing Prp43 to enter a productive interaction with the GP motif of Ntr1. Our data indicate that Ntr1 and Ntr2 act as 'doorkeepers' and suggest that both cofactors inspect the RNP structure of spliceosomal complexes thereby targeting suboptimal spliceosomes for Prp43-mediated disassembly

An EST-SSR Linkage Map of Raphanus sativus and Comparative Genomics of the Brassicaceae†

Raphanus sativus (2n = 2x = 18) is a widely cultivated member of the family Brassicaceae, for which genomic resources are available only to a limited extent in comparison to many other members of the family. To promote more genetic and genomic studies and to enhance breeding programmes of R. sativus, we have prepared genetic resources such as complementary DNA libraries, expressed sequences tags (ESTs), simple sequence repeat (SSR) markers and a genetic linkage map. A total of 26 606 ESTs have been collected from seedlings, roots, leaves, and flowers, and clustered into 10 381 unigenes. Similarities were observed between the expression patterns of transcripts from R. sativus and those from representative members of the genera Arabidopsis and Brassica, indicating their functional relatedness. The EST sequence data were used to design 3800 SSR markers and consequently 630 polymorphic SSR loci and 213 reported marker loci have been mapped onto nine linkage groups, covering 1129.2 cM with an average distance of 1.3 cM between loci. Comparison of the mapped EST-SSR marker positions in R. sativus with the genome sequence of A. thaliana indicated that the Brassicaceae members have evolved from a common ancestor. It appears that genomic fragments corresponding to those of A. thaliana have been doubled and tripled in R. sativus. The genetic map developed here is expected to provide a standard map for the genetics, genomics, and molecular breeding of R. sativus as well as of related species. The resources are available at http://marker.kazusa.or.jp/Daikon

Structural insights into the mechanism of the DEAH-box RNA helicase Prp43.

The DEAH-box helicase Prp43 is a key player in pre-mRNA splicing as well as the maturation of rRNAs. The exact modus operandi of Prp43 and of all other spliceosomal DEAH-box RNA helicases is still elusive. Here, we report crystal structures of Prp43 complexes in different functional states and the analysis of structure-based mutants providing insights into the unwinding and loading mechanism of RNAs. The Prp43ATP-analogRNA complex shows the localization of the RNA inside a tunnel formed by the two RecA-like and C-terminal domains. In the ATP-bound state this tunnel can be transformed into a groove prone for RNA binding by large rearrangements of the C-terminal domains. Several conformational changes between the ATP- and ADP-bound states explain the coupling of ATP hydrolysis to RNA translocation, mainly mediated by a ?-turn of the RecA1 domain containing the newly identified RF motif. This mechanism is clearly different to those of other RNA helicases

From Arabidopsis thaliana to Brassica napus : development of amplified consensus genetic markers (ACGM)for construction of a gene map

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PVDF Sensors for Dynamic Pressure Metrology in Extreme Environment Capteurs PVDF pour la mesure de pression dynamique en environnement extrême

International audienceHigh pressure range, extreme temperature and fast dynamic transient create an extreme environment for accurate pressure measurement. Military applications have a real need for dynamic pressure sensor in order to measure pressure in air blast experiments. Such experiment is a typical extreme pressure measurement application with high temperature and pressure and fast dynamic transient [1]. Structure vulnerability and explosive optimisation need accurate experimental value to improve the accuracy of numerical models [2]. Most of known pressure sensors present a full-scale pressure measurement and bandwidth that are not sufficient for sensing fast pressure variation with high amplitude. The high cutoff frequency of these sensors creates highly undesirable harmonics distortion on the signal and a low (microsecond) rise time. This communication proposes the model and the design of dynamic pressure sensor with nanosecond rise time working in the GPa range in extreme temperature conditions. Based on well-known piezoelectric polymer technologies PVDF [3], key issues related to these sensors such as the packaging, impact of cables and role of the conditioning electronic are addressed in this communication. Based on acoustic/electrical equations analogies [4] the circuit model implementable in Spice software is reported for simulating the sensor response for different excitations such as pulse, unit step or sine function. Thermal protection layers, backing materials, measurement cables and conditioning electronics are taking into account in the sensor simulation and their impacts on the sensor performances are discussed. Moreover the bandwidth, rise time and sensitivity are derived from the proposed simulation model and design rules are given. Finally a PolyVinylidene DiFluoride (PVDF) sensor prototype is presented and shock tube experiment is described [5]. Different shock wave amplitude with nanosecond rise time has been recorded by the designed sensor and rise time, bandwidth and sensitivity have been measured and compared with ones provided by various commercial pressure sensors. The proposed sensor has been calibrated with this shock tube method. Dynamic uncertainties of the sensor have been evaluated based on the work of the EURAMET project [6]

Incident pressure measurement in air blast using wireless sensors

International audienceThis paper presents the wireless measurement of the incident pressure inside the fire ball of an air blast shock wave. The wireless sensor setup and the experimental configuration are described. The wired and wireless experimental results are compared and analyszd. To our best knowledge, it is the first time that a wireless device takes place inside the fireball of an explosion for the measurement of the incident pressure in such harsh environment

The target of the DEAH-box NTP triphosphatase Prp43 in Saccharomyces cerevisiae spliceosomes is the U2 snRNP-intron interaction.

The DEAH-box NTPase Prp43 and its cofactors Ntr1 and Ntr2 form the NTR complex and are required for disassembling intron-lariat spliceosomes (ILS) and defective earlier spliceosomes. However, the Prp43 binding site in the spliceosome and its target(s) are unknown. We show that Prp43 fused to Ntr1's G-patch motif (Prp43_Ntr1GP) is as efficient as the NTR in ILS disassembly, yielding identical dissociation products and recognizing its natural ILS target even in the absence of Ntr1's C-terminal-domain (CTD) and Ntr2. Unlike the NTR, Prp43_Ntr1GP disassembles earlier spliceosomal complexes (A, B, B(act)), indicating that Ntr2/Ntr1-CTD prevents NTR from disrupting properly assembled spliceosomes other than the ILS. The U2 snRNP-intron interaction is disrupted in all complexes by Prp43_Ntr1GP, and in the spliceosome contacts U2 proteins and the pre-mRNA, indicating that the U2 snRNP-intron interaction is Prp43's major target