Phase transition and transition kinetics of a thermotropic poly(amide-imide) derived from 70% pyromellitic dianhydride, 30% terephthaloyl chloride, and 1,3-bis[4-(4 '-aminophenoxy)cumyl]benzene

The phase transition and transition kinetics of a liquid crystalline copoly(amide-imide) (PAI37), which was synthesized from 70 mol% pyromellitic dianhydride, 30 mol% terephthaloyl chloride, and 1,3-bis[4-(4'-aminophenoxy)cumyl]benzene, was characterized by differential scanning calorimetry, polarized light microscopy, X-ray diffraction, and rheology. PAI37 exhibits a glass transition temperature at 182 degreesC followed by multiple phase transitions. The crystalline phase starts to melt at similar to 220 degreesC and forms smectic C (S-C) phase. The Sc phase transforms into smectic A (S-A) phase when the temperature is above 237 degreesC. The S-C to S-A transition spans a broad temperature range in which the S-A phase vanishes and forms isotropic melt. The WARD fiber pattern of PAI37 pulled from the anisotropic melt revealed an anomalous chain orientation, which was characterized by its layer normal perpendicular to the fiber direction. The transition kinetics for the mesophase and crystalline phase formation was also studied.

Densidad de siembra y fertilización nitrogenada en trigo : 1-cultivares Marcos Juárez INTA y Norkinpan 70

p.9-16

40-70 GHz 13 Gbps 1-dB loss SPST and SPDT differential switches in 0.35 μm SiGe technology

This paper presents the design and characterization of ultrafast wideband low-loss single-pole single-throw (SPST) and single-pole double-throw (SPDT) differential switches. The SPDT switch exhibits insertion loss of lower than 1.25 dB from 42 to 70 GHz and isolation of better than 20 dB from 40 to 65 GHz. Similar low-loss and broadband characteristics are also observed from the measured SPST switch. The proposed switch topologies adopting current-steering technique and implemented in 0.35 µm SiGe bipolar technology result in a switching time of only 75 ps. This suggests a maximum switching speed of 13 Gbps, the fastest ever reported at V-band.

Recueil de poésies, par « HENRY BAULDE » (fol. 30, 32, 35, 36, 37, 39, 40, 43, 44, 46, 47, 56, 59, 60, 61, 65, 68, 69, 70, 73, 74), « ALAIN CHARRETIER » (fol. 15), « JEHAN DAUTON » (fol. 9), « JEHAN MAROT » (fol. 29, 30), « JEHAN MOLINET » (fol. 77, 85, 90, 93, 94, 95) et « JEHAN ROBERTET » (fol. 1, 75).

Commençant par : « Estant couché soubz ung myrthe plaisant, Et maintz chasteaulx en Espaigne faisant... » et finissant par : « Sans parage ou riens n'est nect, Moulu d'un groz Moulinet. Fin de la complaincte de Grece, composée par le dict Molinet » .

Étude du rôle des gènes TGF-β1 et HSP-70 lors du processus de régénération du membre chez l’axolotl

Les urodèles amphibiens, dont fait partie l’axolotl (Ambystoma mexicanum), ont la capacité de régénérer leurs organes et membres suite à une amputation, tout au long de leur vie. La patte est l’organe dont le processus de régénération est le mieux caractérisé et ce dernier est divisé en deux phases principales. La première est la phase de préparation et commence immédiatement suite à l’amputation. Elle renferme des étapes essentielles au processus de régénération comme la guérison de la plaie et la formation d’une coiffe apicale ectodermique. Par la suite, les fibroblastes du derme et certaines cellules musculaires vont revenir à un état pluripotent via un processus appelé dédifférenciation cellulaire. Une fois dédifférenciées, ces cellules migrent et s’accumulent sous la coiffe apicale pour former le blastème. Lors de la phase de redéveloppement, les cellules du blastème se divisent puis se redifférencient pour régénérer la partie amputée. Fait intéressant, la régénération d’un membre ou la guérison d’une plaie chez l’axolotl ne mène jamais à la formation d’une cicatrice. Afin d’en apprendre plus sur le contrôle moléculaire de la régénération, les gènes Heat-shock protein-70 (Hsp-70) et Transforming growth factor-β1 (Tgf-β1) ont été sélectionnés. Ces gènes jouent un rôle important dans la réponse au stress et lors de la guérison des plaies chez les mammifères. HSP-70 est une chaperonne moléculaire qui est produite pour maintenir l’intégrité des protéines cellulaires lorsqu’un stress se présente. TGF-β1 est une cytokine produite suite à une blessure qui active la réponse inflammatoire et qui stimule la fermeture de la plaie chez les amniotes. Les résultats présentés dans cette thèse démontrent que Hsp-70 est exprimé et régulé lors du développement et de la régénération du membre chez l’axolotl. D’autre part, nos expériences ont mené à l’isolation de la séquence codante pour Tgf-β1 chez l’axolotl. Nos résultats montrent que Tgf-β1 est exprimé spécifiquement lors de la phase de préparation dans le membre en régénération. De plus, le blocage de la voie des Tgf-β avec l’inhibiteur pharmacologique SB-431542, lors de la régénération, mène à l’inhibition du processus. Ceci démontre que la signalisation via la voie des Tgf-β est essentielle à la régénération du membre chez l’axolotl.

The role of conserved region 1 of Escherichia coli sigma-70 in transcription initiation

The sigma (σ) subunit of eubacterial RNA polymerase is essential for initiation of transcription at promoter sites. σ factor directs the RNA polymerase core subunits ( a2bb′ ) to the promoter consensus elements and thereby confers selectivity for transcription initiation. The N-terminal domain (region 1.1) of Escherichia coli σ70 has been shown to inhibit DNA binding by the C-terminal DNA recognition domains when σ is separated from the core subunits. Since DNA recognition by RNA polymerase is the first step in transcription, it seemed plausible that region 1 might also influence initiation processes subsesquent to DNA binding. This study explores the functional roles of regions 1.1 and 1.2 of σ70 in transcription initiation. Analysis in vitro of the transcriptional properties of a series of N-terminally truncated σ70 derivates revealed a critical role for region 1.1 at several key stages of initiation. Deletion of the first 75 to 100 amino acids of σ70 (region 1.1) resulted in both a slow rate of transition from a closed promoter complex to a DNA-strand-separated open complex, as well as a reduced efficiency of transition from the open complex to a transcriptionally active open complex. These effects were partially reversed by addition of a polypeptide containing region 1.1 in trans. Therefore, region 1.1 not only modulates DNA binding but is important for efficient transcription initiation, once a closed complex has formed. A deletion of the first 133 amino acids which removes both regions 1.1 and 1.2 resulted in arrest of initiation at the earliest closed complex, suggesting that region 1.2 is required for open complex formation. Mutagenesis of region 1.1 uncovered a mechanistically important role for isoleucine at position 53 (I53). Substitution of I53 with alanine created a σ factor that associated with the core subunits to form holoenzyme, but the holoenzyme was severely deficient for promoter binding. The I53A phenotype was suppressed in vivo by truncation of five amino acids from the C-terminus of σ 70. These observations are consistent with a model in which σ 70I53A fails to undergo a critical conformational change upon association with the core subunits, which is needed to expose the DNA-binding domains and confer promoter recognition capability upon holoenzyme. To understand the basis of the autoinhibitory properties of the σ70 N-terminal domain, in the absence of core RNA polymerase, a preliminary physical assessment of the interdomain interactions within the σ70 subunit was launched. Results support a model in which N-terminal amino acids are in close proximity to residues in the C-terminus of the σ 70 polypeptide. ^

An analysis of the function of region 1.2 of the primary sigma factor, sigma 70, from Escherichia coli

The sigma (σ) subunit of eubacterial RNA polymerase is required for recognition of and transcription initiation from promoter DNA sequences. One family of sigma factors includes those related to the primary sigma factor from E. coli, σ70. Members of the σ70 family have four highly conserved domains, of which regions 2 through 4 are present in all members. Region 1 can be subdivided into regions 1.1 and 1.2. Region 1.1 affects DNA binding by σ 70 alone, as well as transcription initiation by holoenzyme. Region 1.2, present and highly conserved in most sigma factors, has not yet been assigned a putative function, although previous work demonstrated that it is not required for either association with the core subunits of RNA polymerase or promoter specific binding by holoenzyme. This study primarily investigates the functional role of region 1.2 during transcription initiation. In vivo and in vitro characterization of thirty-two single amino acid substitutions targeted to region 1.2 of E. coli σ70 as well as a deletion of region 1.2, revealed that mutations in region 1.2 can affect promoter binding, open complex formation, initiated complex formation, and the transition from abortive transcription to elongation. The relative degree of solvent exposure of several positions in region 1.2 has been determined, with positions 116 and 122 likely to be located near the surface of σ70. ^ During the course of this study, the existence of two “wild type” variants of E. coli σ70 was discovered. The identity of amino acid 149 has been reported variably as either arginine or aspartic acid in published articles and in online databases. In vivo and in vitro characterization of the two reported variations of E. coli σ70 (N149 and D149) has determined that the two variants are functionally equivalent. However, in vivo and in vitro characterization of single amino acid substitutions and a region 1.2 deletion in the context of each variant background revealed that the behavior of some mutations are greatly affected by the identity of amino acid 149. ^

Ms. lat. oct. 70 Bd. 1 - Commentarii iuridici (Tomus primus iuris utriusque)

Vorbesitzer: Johann Ludwig von Hagen