Synthesis of monochlorosilyl derivatives of dialkyloligothiophenes for self-assembling monolayer field-effect transistors

Unsymmetrical dimethylchlorosilyl-substituted α, α′- dialkylquater-, quinque-, and sexithiophenes were designed and successfully synthesized by a combination of Kumada and Suzuki cross-coupling reactions followed by hydrosilylation. Optimization possibilities of the hydrosilylation of low-soluble linear oligothiophenes by dimethylchlorosilane as well as the nonreactive byproducts formed are described. The molecular structures of the obtained dimethylchlorosilyl-functionalized oligothiophenes were proven by NMR and DCI MS techniques. These compounds were found to be stable and reactive enough, even in the presence of the nonreactive byproducts, to form semiconducting monolayers on dielectric hydroxylated SiO2 surfaces by self-assembly from solution. The semiconducting properties of these oligothiophene SAMs were as good as those of bulk oligothiophenes. This allowed the production of stable, even under ambient conditions, SAMFETs with a mobility of up to 0.04 cm2/(V s) and an on/off ratio up to 1 × 10 8. © 2010 American Chemical Society

Genes involved in brassinosteroids's metabolism and signal transduction pathways Genes envolvidos nas vias de biossíntese e de transdução de sinal de brassinoesteróides

Brassinosteroids (BRs) are plant steroids essential for the normal growth and development, which carry an oxygen moiety at C-3 and additional ones at one or more of the C-2, C-6, C-22 and C-23 carbon atoms. In the past few years, application of molecular genetics allowed significant progress on the understanding of the BRs biosynthetic pathway regulation and on the identification of several components of their signal transduction pathway, as well. Search in eletronic databases show dozens of records for brassinosteroid-related genes for the last twelve months, demonstrating the big efforts being carried out in this field. This review highlights the recent advances on the characterization of genes and mutations that are helping to unravel the molecular mechanisms involved in the BRs synthesis/metabolism, perception and response, with especial emphasis on their role in plant cell elongation. Aspects of the involvement of BRs on the regulation of cell cycle-controlling proteins are discussed as well.<br>Brassinoesteróides são esteróides vegetais, essenciais para o crescimento e o desenvolvimento, que apresentam um oxigênio no carbono C-3 e oxigênios adicionais em um ou mais dos átomos de carbono C-2, C-6, C-22 e C-23. Nos últimos anos, a aplicação de técnicas de genética molecular possibilitou progresso significativo no entendimento da regulação da via biossintética e na identificação de vários componentes da via de transdução de sinal de brassinoesteróides. Buscas em bases de dados eletrônicas mostram dúzias de registros para genes relacionados a brassinoesteróides nos últimos doze meses, demonstrando os grandes esforços desenvolvidos neste campo. Esta revisão destaca os recentes avanços na caracterização de genes e mutações que estão auxiliando na elucidação dos mecanismos moleculares envolvidos na síntese/metabolismo, e percepção e resposta de brassinoesteróides, com ênfase especial no seu papel no alongamento de células vegetais. Aspectos do envolvimento de BRs na regulação de proteínas que controlam o ciclo cellular também são discutidos