Unnatural amino acid mutagenesis requires the in vitro production of aminoacyl tRNAs. Bacteriophage T4 RNA ligase is used to ligate α-amino-protected dCA amino acids to 74mer tRNA. Previously, there has been no facile method for evaluating the efficiency of this reaction prior to using the tRNA in translation. We report a novel use of matrix-assisted laser desorption/ionization (MALDI) mass spectrometry in monitoring the formation of aminoacyl 76mer tRNA. This method is more efficient and precise than the traditional technique of gel electrophoresis. These MALDI conditions should also prove useful for analyzing aminoacyl tRNAs produced through aminoacyl tRNA synthetases and other methods.

Preparation of large quantities of RNA molecules of a defined sequence is a prerequisite for biophysical analysis, and is particularly important to the determination of high-resolution structure by X-ray crystallography. We describe improved methods for the production of multimilligram quantities of homogeneous tRNAs, using a combination of chemical synthesis and enzymatic approaches. Transfer RNA half-molecules with a break in the anticodon loop were chemically synthesized on a preparative scale, ligated enzymatically, and cocrystallized with an aminoacyl-tRNA synthetase, yielding crystals diffracting to 2.4 Å resolution. Multimilligram quantities of tRNAs with greatly reduced 3′ heterogeneity were also produced via transcription by T7 RNA polymerase, utilizing chemically modified DNA half-molecule templates. This latter approach eliminates the need for large-scale plasmid preparations, and yields synthetase cocrystals diffracting to 2.3 Å resolution at much lower RNA:protein stoichiometries than previously required. These two approaches developed for a tRNA–synthetase complex permit the detailed structural study of “atomic-group” mutants.

Compelling in vivo studies suggest a tight functional linkage between RNA polymerase II transcription and pre-messenger RNA splicing. At present, the specific interactions involved in this coupling are poorly understood and deserve investigation. To this end, we developed an in vitro system that permits study of coupled transcription and splicing. Transcripts generated by RNA polymerase II were accurately and efficiently spliced under reaction conditions that permitted both transcription and splicing to occur simultaneously. The splicing of RNA-polymerase-II-driven transcripts was accelerated relative to that of the same transcripts driven by T7 RNA polymerase. Moreover, the product of exon ligation was found associated with the DNA template in reactions driven by RNA polymerase II. These two findings indicate that transcription and splicing were coupled in the in vitro system driven by RNA polymerase II, and suggest that this system will be useful for the biochemical study of this coupling.

The use of double-stranded RNA (dsRNA) to disrupt gene expression has become a powerful method of achieving RNA interference (RNAi) in a wide variety of organisms. However, in Trypanosoma brucei this tool is restricted to transient interference, because the dsRNA is not stably maintained and its effects are diminished and eventually lost during cellular division. Here, we show that genetic interference by dsRNA can be achieved in a heritable and inducible fashion. To show this, we established stable cell lines expressing dsRNA in the form of stem-loop structures under the control of a tetracycline-inducible promoter. Targeting α-tubulin and actin mRNA resulted in potent and specific mRNA degradation as previously observed in transient interference. Surprisingly, 10-fold down regulation of actin mRNA was not fatal to trypanosomes. This type of approach could be applied to study RNAi in other organisms that are difficult to microinject or electroporate. Furthermore, to quickly probe the consequences of RNAi for a given gene we established a highly efficient in vivo T7 RNA polymerase system for expression of dsRNA. Using the α-tubulin test system we obtained greater than 98% transfection efficiency and the RNAi response lasted at least two to three cell generations. These new developments make it possible to initiate the molecular dissection of RNAi both biochemically and genetically.

DNA templates modified with C2′-methoxyls at the last two nucleotides of the 5′ termini dramatically reduced nontemplated nucleotide addition by the T7 RNA polymerase from both single- and double-stranded DNA templates. This strategy was used to generate several different transcripts. Two of the transcripts were demonstrated by nuclear magnetic resonance spectroscopy to be unaffected in their sequence. Transcripts produced from the modified templates can be purified with greater ease and should be useful in a number of applications.