Haplotypes of the cholesteryl ester transfer protein gene predict lipid-modifying response to statin therapy.

Cholesteryl ester transfer protein (CETP) plays a central role in high-density lipoprotein (HDL) metabolism. Single nucleotide polymorphisms (SNPs) and haplotypes in the CETP gene were determined in 98 patients with untreated dyslipidemias and analyzed for associations with plasma CETP and plasma lipids before and during statin treatment. Individual CETP SNPs and haplotypes were both significantly associated with CETP enzyme mass and activity. However, only certain CETP haplotypes, but not individual SNPs, significantly predicted the magnitude of change in HDL cholesterol (HDL-C) and triglycerides. After adjusting for covariates and multiple testing, the TTCAAA haplotype showed a gene-dose effect in predicting the HDL-C increase (P=0.03), while the TTCAAAGGG and AAAGGG haplotypes predicted a decrease in triglycerides (P=0.04 both). This is the first study to demonstrate that SNP haplotypes derived from allelic SNP combinations in the CETP gene were more informative than single SNPs in predicting the response to lipid-modifying therapy with statins.

Haplotype variation and linkage disequilibrium in 313 human genes.

Variation within genes has important implications for all biological traits. We identified 3899 single nucleotide polymorphisms (SNPs) that were present within 313 genes from 82 unrelated individuals of diverse ancestry, and we organized the SNPs into 4304 different haplotypes. Each gene had several variable SNPs and haplotypes that were present in all populations, as well as a number that were population-specific. Pairs of SNPs exhibited variability in the degree of linkage disequilibrium that was a function of their location within a gene, distance from each other, population distribution, and population frequency. Haplotypes generally had more information content (heterozygosity) than did individual SNPs. Our analysis of the pattern of variation strongly supports the recent expansion of the human population.

Complex promoter and coding region beta 2-adrenergic receptor haplotypes alter receptor expression and predict in vivo responsiveness.

The human beta(2)-adrenergic receptor gene has multiple single-nucleotide polymorphisms (SNPs), but the relevance of chromosomally phased SNPs (haplotypes) is not known. The phylogeny and the in vitro and in vivo consequences of variations in the 5' upstream and ORF were delineated in a multiethnic reference population and an asthmatic cohort. Thirteen SNPs were found organized into 12 haplotypes out of the theoretically possible 8,192 combinations. Deep divergence in the distribution of some haplotypes was noted in Caucasian, African-American, Asian, and Hispanic-Latino ethnic groups with >20-fold differences among the frequencies of the four major haplotypes. The relevance of the five most common beta(2)-adrenergic receptor haplotype pairs was determined in vivo by assessing the bronchodilator response to beta agonist in asthmatics. Mean responses by haplotype pair varied by >2-fold, and response was significantly related to the haplotype pair (P = 0.007) but not to individual SNPs. Expression vectors representing two of the haplotypes differing at eight of the SNP loci and associated with divergent in vivo responsiveness to agonist were used to transfect HEK293 cells. beta(2)-adrenergic receptor mRNA levels and receptor density in cells transfected with the haplotype associated with the greater physiologic response were approximately 50% greater than those transfected with the lower response haplotype. The results indicate that the unique interactions of multiple SNPs within a haplotype ultimately can affect biologic and therapeutic phenotype and that individual SNPs may have poor predictive power as pharmacogenetic loci.

Binding of a cell-type-specific RNA splicing factor to its target regulatory sequence.

The transcript of the Saccharomyces cerevisiae MER2 gene is spliced efficiently during meiosis but not during vegetative growth. Efficient splicing of the wild-type MER2 transcript requires the Mer1 protein, which is produced only in meiotic cells. Analysis of deletion and substitution mutations in the MER2 5' exon demonstrates that the unusually large size of this exon plays an important role in splicing regulation. The cis-acting sequences essential for Mer1-dependent splicing of MER2 RNA were determined by the analysis of MER2 deletion mutants and hybrid genes. The 80-base MER2 intron is sufficient for Mer1-dependent splicing in vivo, but sequences in the 5' exon enhance splicing efficiency. The Mer1 protein contains the KH motif found in some RNA-binding proteins, and RNA gel mobility shift assays demonstrate that Mer1 binds specifically to MER2 RNA. Both the transcript derived from the intronless MER2 gene and the transcript consisting only of the intron are able to bind to Mer1 in vitro, but neither has as high affinity for the protein as the intact substrate. RNase T1 footprinting indicates that the Mer1 protein contacts MER2 RNA at several points in the 5' exon and in the intron. Thus, Mer1 interacts directly with a regulatory element in MER2 RNA and promotes splicing.

Mutations in U1 snRNA bypass the requirement for a cell type-specific RNA splicing factor.

Previous studies have demonstrated that efficient splicing of the primary transcript of the yeast MER2 gene requires the MER1 protein, which is produced only in meiotic cells. A genetic selection was devised to recover second-site mutations that bypass the requirement for MER1 in MER2 RNA-splicing. This selection identified a mutation in SNR19, the gene for U1 snRNA. The suppressor mutation affects the first residue in U1 snRNA, allowing this nucleotide to base pair with the eighth nucleotide in the MER2 intron. This base in MER2 lies outside the conserved hexanucleotide that defines the 5' splice site in yeast. The MER2 5' splice site (GUUCGU) differs from the consensus in yeast (GUAYGU) at the third position. When this nucleotide is mutated to restore the consensus, base pairing with U1 snRNA is increased and the requirement for MER1 is alleviated.

Identification of base and backbone contacts used for DNA sequence recognition and high-affinity binding by LAC9, a transcription activator containing a C6 zinc finger.

The LAC9 protein of Kluyveromyces lactis is a transcriptional regulator of genes in the lactose-galactose regulon. To regulate transcription, LAC9 must bind to 17-bp upstream activator sequences (UASs) located in front of each target gene. LAC9 is homologous to the GAL4 protein of Saccharomyces cerevisiae, and the two proteins must bind DNA in a very similar manner. In this paper we show that high-affinity, sequence-specific binding by LAC9 dimers is mediated primarily by 3 bp at each end of the UAS: [Formula: see text]. In addition, at least one half of the UAS must have a GC or CG base pair at position 1 for high-affinity binding; LAC9 binds preferentially to the half containing the GC base pair. Bases at positions 2, 3, and 4 in each half of the UAS make little if any contribution to binding. The center base pair is not essential for high-affinity LAC9 binding when DNA-binding activity measured in vitro. However, the center base pair must play an essential role in vivo, since all natural UASs have 17, not 16, bp. Hydroxyl radical footprinting shows that a LAC9 dimer binds an unusually broad region on one face of the DNA helix. Because of the data, we suggest that LAC9 contacts positions 6, 7, and 8, both plus and minus, of the UAS, which are separated by more than one turn of the DNA helix, and twists part way around the DNA, thus protecting the broad region of the minor groove between the major-groove contacts.

LAC9 DNA-binding domain coordinates two zinc atoms per monomer and contacts DNA as a dimer.

The LAC9 protein of Kluyveromyces lactis activates transcription by binding to upstream activating sequences lying in front of genes of the lactose-galactose regulon. LAC9 belongs to a family of fungal proteins having a conserved domain containing 6 cysteines. This domain, termed a C6 zinc finger, is thought to bind one zinc atom and to play a vital role in DNA binding. To further characterize the DNA-binding domain of LAC9, we have developed a procedure to produce and to purify milligram amounts of LAC9 peptides. The two larger peptides, one containing amino acids 1-228 and the other containing amino acids 85-228, formed dimers in solution and bound DNA specifically as a dimer. The smallest LAC9 peptide, amino acids 85-160, failed to dimerize and did not bind DNA. Atomic absorption spectroscopy revealed that each LAC9 monomer coordinated two zinc atoms, not one, as had been predicted. This result suggests, as does previously published data, that the C6 zinc finger domain has a unique conformation that may represent a new type of DNA-binding motif.

A minor 9.8 kb rDNA unit of rice variety IR-20.

A clone bearing a 9.8 kb EcoRI fragment of rice DNA containing the genes for the rRNAs and the intergenic spacer was identified by screening a rice genomic library in lambda Charon 4 phage with rRNAs. The 9.8 kb EcoRIDNA fragment was found to be a minor rDNA unit of rice variety IR-20. The rRNA genes and the intergenic spacer were mapped by hybridization and nucleotide sequence analyses. The DNAs in the intergenic spacer of the minor rDNA unit of 9.8 kb and the major rDNA unit of 8.9 kb cross-hybridized showing that those regions are homologous.

Initiation of transcription of rDNA in rice.

Three direct repeats of 320, 340 and 238 nucleotides were detected upstream to the 5' end of the 18S rRNA gene of an rDNA unit present on a 9.8 kb EcoRI fragment of the rice DNA. The primer extension analysis showed that the site of initiation of transcription is in the 1st repeat at an A, the 623rd nucleotide upstream to the 5' end of the 18S rRNA gene. Different stretches of the intergenic spacer DNA linked to the Chloramphenicol acetyl transferase gene were transcribed in the intact nuclei of rice embryos. The S1 nuclease protection analysis of the transcripts using [32P]-labelled Chloramphenicol acetyl transferase gene as the probe showed the presence of multiple promoters for rDNA transcription.

Putative termination sites for rDNA transcription in rice.

A clone bearing a 9.8 kb insert DNA containing the rDNA unit was identified by screening an EcoR1 library of rice DNA in lambda Charon 4 phage with [32P]-rRNAs. The S1 nuclease mapping of the rDNA-precursor rRNA hybrids showed the presence of two transcription termini on the rDNA. They were mapped at positions 616 and 620 nucleotides downstream to the end of the 25S rRNA gene. The 18 nucleotide sequence, where the transcription terminates on the rDNA in rice and mice are homologous albeit in the reverse orientation.