Comprehensive genome scans involving many thousands of SNP assays will require significant amounts of genomic DNA from each sample. We report two successful methods for amplifying whole-genomic DNA prior to SNP analysis, multiple displacement amplification, and OmniPlex technology. We determined the coverage of amplification by analyzing a SNP linkage marker set that contained 2320 SNP markers spread across the genome at an average distance of 2.5 cM. We observed a concordance of >99.8% in genotyping results from genomic DNA and amplified DNA, strongly indicating the ability of both methods used to amplify genomic DNA in a highly representative manner. Furthermore, we were able to achieve a SNP call rate of >98% in both genomic and amplified DNA. The combination of whole-genome amplification and comprehensive SNP linkage analysis offers new opportunities for genetic analysis in clinical trials, disease association studies, and archiving of DNA samples.
This unit provides thorough coverage of the most useful chemical and enzyme probes that can be used to examine RNA secondary and tertiary structure. Footprinting methods are presented using dimethyl sulfate, diethyl pyrocarbonate, ethylnitrosourea, kethoxal, CMCT, and nucleases. For chemical probes, both strand scission and primer extension detection protocols are included.
Eukaryotic RNase P and RNase MRP are endoribonucleases composed of RNA and protein subunits. The RNA subunits of each enzyme share substantial secondary structural features, and most of the protein subunits are shared between the two. One of the conserved RNA subdomains, designated P3, has previously been shown to be required for nucleolar localization. Phylogenetic sequence analysis suggests that the P3 domain interacts with one of the proteins common to RNase P and RNase MRP, a conclusion strengthened by an earlier observation that the essential domain can be interchanged between the two enzymes. To examine possible functions of the P3 domain, four conserved nucleotides in the P3 domain of Saccharomyces cerevisiae RNase P RNA (RPR1) were randomized to create a library of all possible sequence combinations at those positions. Selection of functional genes in vivo identified permissible variations, and viable clones that caused yeast to exhibit conditional growth phenotypes were tested for defects in RNase P RNA and tRNA biosynthesis. Under nonpermissive conditions, the mutants had reduced maturation of the RPR1 RNA precursor, an expected phenotype in cases where RNase P holoenzyme assembly is defective. This loss of RPR1 RNA maturation coincided, as expected, with a loss of pre-tRNA maturation characteristic of RNase P defects. To test whether mutations at the conserved positions inhibited interactions with a particular protein, specific binding of the individual protein subunits to the RNA subunit was tested in yeast using the threehybrid system. Pop1p, the largest subunit shared by RNases P and MRP, bound specifically to RPR1 RNA and the isolated P3 domain, and this binding was eliminated by mutations at the conserved P3 residues. These results indicate that Pop1p interacts with the P3 domain common to RNases P and MRP, and that this interaction is critical in the maturation of RNase P holoenzyme.
Eukaryotic transfer RNA precursors (pre-tRNAs) contain a 5' leader preceding the aminoacyl acceptor stem and a 3' trailer extending beyond this stem. An early step in pre-tRNA maturation is removal of the 5' leader by the endoribonuclease, RNase P. Extensive pairing between leader and trailer sequences has previously been demonstrated to block RNase P cleavage, suggesting that the 5' leader and 3' trailer sequences might need to be separated for the substrate to be recognized by the eukaryotic holoenzyme. To address whether the nuclear RNase P holoenzyme recognizes the 5' leader and 3' trailer sequences independently, interactions of RNase P with pre-tRNA(Tyr) containing either the 5' leader, the 3' trailer, or both were examined. Kinetic analysis revealed little effect of the 3' trailer or a long 5' leader on the catalytic rate (k(cat)) for cleavage using the various pre-tRNA derivatives. However, the presence of a 3' trailer that pairs with the 5' leader increases the K(m) of pre-tRNA slightly, in agreement with previous results. Similarly, competition studies demonstrate that removal of a complementary 3' trailer lowers the apparent K(I), consistent with the structure between these two sequences interfering with their interaction with the enzyme. Deletion of both the 5' and 3' extensions to give mature termini resulted in the least effective competitor. Further studies showed that the nuclear holoenzyme, but not the B. subtilis holoenzyme, had a high affinity for single-stranded RNA in the absence of attached tRNA structure. The data suggest that yeast nuclear RNase P contains a minimum of two binding sites involved in substrate recognition, one that interacts with tRNA and one that interacts with the 3' trailer. Furthermore, base pairing between the 5' leader and 3' trailer hinders recognition.
The P10/11-P12 RNA domain of yeast RNase P contains several highly conserved nucleotides within a conserved secondary structure. This RNA domain is essential for enzyme function in vivo, where it has a demonstrated role in divalent cation utilization. To better understand the function of this domain, its structure and alterations in response to magnesium have been investigated in vitro. A secondary structure model of the P10/11-P12 RNA domain had been previously developed by phylogenetic analysis. Computer modeling and energy minimization were applied to the Saccharomyces cerevisiae P10/11-P12 domain to explore alternatives and additional interactions not predicted by the phylogenetic consensus. The working secondary structure models were challenged with data obtained from 1H NMR and in vitro chemical and enzymatic probing experiments. The solution structure of the isolated domain was found to conform to the phylogenetic prediction within the context of the holoenzyme. Structure probing data also discriminated among additional base contacts predicted by energy minimization. The withdrawal of magnesium does not appear to cause gross refolding or rearrangement of the RNA domain structure. Instead, subtle changes occur in the solution accessibility of specific nucleotide positions. Most of the conserved nucleotides reported to be involved in magnesium utilization in vivo also display magnesium-dependent changes in vitro.
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