In vitro binding to the leucine tRNA gene identifies a novel yeast homeobox gene

In a search for gene products of Saccharomyces cerevisiae interacting with the internal promoter of yeast tRNA genes two genes encoding a homeodomain protein of the Drosophila Antennapedia type were isolated. One of them codes for Pho2, and the second codes for a previously unknown protein (Yox1). The corresponding gene, termed YOX1, maps to chromosome 16. The amino acid sequence of Yox1 shows a remarkable similarity within the homeobox domain to many proteins from a wide variety of sources. Fusion proteins that contain sequences encoded by these genes demonstrate that the genes encode DNA-binding proteins that are capable of binding to the DNA of the leucine tRNA gene in vitro. However, deletion of YOX1 gene activity does not give rise to a scorable mutant phenotype. This result leaves open whether Yox1 binding to the leucine tRNA gene is necessary for the in vivo regulaiton of the gene and its suggests that the YOX1 gene codes for a nonessential product.by H. JäckleThe sequence data reported here will appear in the EMBL, Gen-Bank and DDBJ Nucleotide Sequence Databases under the accession number X62392     

The use of a synthetic DNA-antibody complex as external reference for chromatin immunoprecipitation

Chromatin immunoprecipitation (ChIP) is an analytical method used to investigate the interactions between proteins and DNA in vivo. ChIP is often used as a quantitative tool, and proper quantification relies on the use of adequate references for data normalization. However, many ChIP experiments involve analyses of samples that have been submitted to experimental treatments with unknown effects, and this precludes the choice of suitable internal references. We have developed a normalization method based on the use of a synthetic DNA-antibody complex that can be used as an external reference instead. A fixed amount of this synthetic DNA-antibody complex is spiked into the chromatin extract at the beginning of the ChIP experiment. The DNA-antibody complex is isolated together with the sample of interest, and the amounts of synthetic DNA recovered in each tube are measured at the end of the process. The yield of synthetic DNA recovery in each sample is then used to normalize the results obtained with the antibodies of interest. Using this approach, we could compensate for losses of material, reduce the variability between ChIP replicates, and increase the accuracy and statistical resolution of the data.     

The primary structure of yeast mitochondrial tyrosine tRNA

The mitochondrial tyrosine tRNA from Saccharomyces cerevisiae has been sequenced. It has two interesting structural features: (i) it lacks two semi-invariant purine residues in the D-loop which are involved in tertiary interactions in the yeast cytoplasmic tRNAPhe; (ii) it has a large variable loop and therefore resembles procaryotic tRNAsTyr rather than eucaryotic cytoplasmic ones.     

The chromatin structure of an actively expressed, single copy yeast gene.

When the yeast galactokinase gene is not active (repressed, not expressed, quiescent), there is an exceptionally regular nucleosome array on coding sequence galactokinase chromatin, as shown by both denaturing and non-denaturing gel analysis of staphylococcal nuclease digests. Expression of the gene results in a limited smearing of the nucleosome repeat peaks and an increase in interpeak DNA, appearing as a regular ladder of DNA bands on denaturing gels. On non-denaturing gels the pattern is more complex and molecular weight dependent. These data suggest an increase in intracore particle DNA accessibility, allowing staphylococcal nuclease to digest throughout the nucleosome in expressed chromatin. Comparison to bulk chromatin and to an operationally inactive gene (35S rDNA) show that the alteration is specific to expressed chromatin. In contrast, DNase I shows no differences in the digestion of the gene specific chromatin in expressed or inactive states.     

A synthetic alanyl-initiator tRNA with initiator tRNA properties as determined by fluorescence measurements: comparison to a synthetic alanyl-elongator tRNA.

Two synthetic tRNAs have been generated that can be enzymatically aminoacylated with alanine and have AAA anticodons to recognize a poly(U) template. One of the tRNAs (tRNA(eAla/AAA)) is nearly identical to Escherichia coli elongator tRNA(Ala). The other has a sequence similar to Escherichia coli initiator tRNA(Met) (tRNA(iAla/AAA)). Although both tRNAs can be used in poly(U)-directed nonenzymatic initiation at 15 mM Mg2+, only the elongator tRNA can serve for peptide elongation and polyalanine synthesis. Only the initiator tRNA can be bound to 30S ribosomal subunits or 70S ribosomes in the presence of initiation factor 2 (IF-2) and low Mg2+ suggesting that it can function in enzymatic peptide initiation. A derivative of coumarin was covalently attached to the alpha amino group of alanine of these two Ala-tRNA species. The fluorescence spectra, quantum yield and anisotropy for the two Ala-tRNA derivatives are different when they are bound to 70S ribosomes (nonenzymatically in the presence of 15 mM Mg2+) indicating that the local environment of the probe is different. Also, the effect of erythromycin on their fluorescence is quite different, suggesting that the probes and presumably the alanine moiety to which they are covalently linked are in different positions on the ribosomes.