Assessing the Drosophila melanogaster and Anopheles gambiae genome annotations using genome-wide sequence comparisons

We performed genome-wide sequence comparisons at the protein coding level between the genome sequences of Drosophila melanogaster and Anopheles gambiae. Such comparisons detect evolutionarily conserved regions (ecores) that can be used for a qualitative and quantitative evaluation of the available annotations of both genomes. They also provide novel candidate features for annotation. The percentage of ecores mapping outside annotations in the A. gambiae genome is about fourfold higher than in D. melanogaster. The A. gambiae genome assembly also contains a high proportion of duplicated ecores, possibly resulting from artefactual sequence duplications in the genome assembly. The occurrence of 4063 ecores in the D. melanogaster genome outside annotations suggests that some genes are not yet or only partially annotated. The present work illustrates the power of comparative genomics approaches towards an exhaustive and accurate establishment of gene models and gene catalogues in insect genomes.     

Active chromatin domains are defined by acetylation islands revealed by genome-wide mapping

The identity and developmental potential of a human cell is specified by its epigenome that is largely defined by patterns of chromatin modifications including histone acetylation. Here we report high-resolution genome-wide mapping of diacetylation of histone H3 at Lys 9 and Lys 14 in resting and activated human T cells by genome-wide mapping technique (GMAT). Our data show that high levels of the H3 acetylation are detected in gene-rich regions. The chromatin accessibility and gene expression of a genetic domain is correlated with hyperacetylation of promoters and other regulatory elements but not with generally elevated acetylation of the entire domain. Islands of acetylation are identified in the intergenic and transcribed regions. The locations of the 46,813 acetylation islands identified in this study are significantly correlated with conserved noncoding sequences (CNSs) and many of them are colocalized with known regulatory elements in T cells. TCR signaling induces 4045 new acetylation loci that may mediate the global chromatin remodeling and gene activation. We propose that the acetylation islands are epigenetic marks that allow prediction of functional regulatory elements.     

Clustering patterns of LOD scores for asthma-related phenotypes revealed by a genome-wide screen in 295 French EGEA families

A genome-wide scan for asthma phenotypes was conducted in the whole sample of 295 EGEA families selected through at least one asthmatic subject. In addition to asthma, seven phenotypes involved in the main asthma physiopathological pathways were considered: SPT (positive skin prick test response to at least one of 11 allergens), SPTQ score being the number of positive skin test responses to 11 allergens, Phadiatop (positive specific IgE response to a mixture of allergens), total IgE levels, eosinophils, bronchial responsiveness (BR) to methacholine challenge and %predicted FEV(1). Four regions showed evidence for linkage (P相似文献   

Singleton SNPs in the human genome and implications for genome-wide association studies

The human genome is estimated to contain one single nucleotide polymorphism (SNP) every 300 base pairs. The presence of LD between SNP markers can be used to save genotyping cost via appropriate SNP tagging strategies, whereas absence or low level of LD between markers generally increase genotyping cost. It is quite common that a large proportion of tagging SNPs in a tagging scheme often turn out to be singleton SNPs, that is, SNPs that only tag themselves rather than contribute power to the rest of a region. If genotyping cost is a major concern, which often is the case at the present time for genome-wide association studies, these singleton tagging SNPs would be the primary targets to be removed from genotyping. It is important, however, to understand the characteristics of such SNPs and estimate the impact of removing them in a study. Using the HapMap genotype data and genome wide expression data, we assessed the distribution and functional implications of singleton SNPs in the human genome. Our results demonstrated that SNPs of potentially higher functional importance (eg, nonsynonymous SNPs, SNPs in splicing sites and SNPs in 5' and 3' UTR) are associated with a higher tendency to be singleton SNPs than SNPs in intronic and intergenic regions. We further assessed whether singleton SNPs can be tagged using haplotypes of tagSNPs in the three genome wide chips, that is, GeneChip 500k of Affymetrix, HumanHap300 and HumanHap550 of Illumina, and discussed the general implications on genetic association studies.     

Effects of dexamethazone on LPS-induced activationand migration of mouse dendritic cells revealed by a genome-wide transcriptional analysis

While lipopolysaccharides (LPS) induce dendritic cell (DC) maturation and migration to lymph nodes, glucocorticoids such as dexamethazone (Dex) have a profound suppressive effect on immune response. The mechanisms that might control this suppressive effect of Dex have been extensively investigated in lymphocytes as possible targets. Much less is known on the effects of Dex on DC, although they are recognized to regulate immunity. To get insights into possible combined effects of Dex and LPS on DC functions, we have undertaken a genome-wide analysis of differentially expressed genes of DC treated with Dex alone, LPS alone, or both, using high-density oligonucleotide microarrays. Hierarchical clustering and principal component analysis (PCA) agreed in identifying 24 h as the time point that best discriminated the three treatments. Among the counteracting effects we have observed an inhibition of Dex on the LPS-induced up-regulation of the chemokine receptor CCR7. In vivo, Dex treatment blocked the LPS-induced migration of DC, which lost their ability to reach the draining lymph nodes. In addition, we observed a synergistic effect of Dex and LPS on the expression of the secreted lipocalin 24p3, which has been reported to induce apoptosis in T cells and thus may be related to immune suppression.     

Identification of genes that protect the C. elegans genome against mutations by genome-wide RNAi

An RNA interference (RNAi)-based genome-wide screen was performed to detect genes that contribute to genome stability in somatic cells of Caenorhabditis elegans. We identified 61 such genes; these also affect spontaneous mutagenesis in the germ line. Their sequence suggests a role in DNA repair and/or replication, in chromatin remodeling, or in cell cycle control; there are also many novel genes that are highly conserved from yeast to human. Because known mutator genes are causally involved in many hereditary and sporadic human cancers, it is likely that some of these new mutators are equally relevant in cancer etiology.     

Neuropeptides and neuropeptide receptors in the Drosophila melanogaster genome

Recent genetic analyses in worms, flies, and mammals illustrate the importance of bioactive peptides in controlling numerous complex behaviors, such as feeding and circadian locomotion. To pursue a comprehensive genetic analysis of bioactive peptide signaling, we have scanned the recently completed Drosophila genome sequence for G protein-coupled receptors sensitive to bioactive peptides (peptide GPCRs). Here we describe 44 genes that represent the vast majority, and perhaps all, of the peptide GPCRs encoded in the fly genome. We also scanned for genes encoding potential ligands and describe 22 bioactive peptide precursors. At least 32 Drosophila peptide receptors appear to have evolved from common ancestors of 15 monophyletic vertebrate GPCR subgroups (e.g., the ancestral gastrin/cholecystokinin receptor). Six pairs of receptors are paralogs, representing recent gene duplications. Together, these findings shed light on the evolutionary history of peptide GPCRs, and they provide a template for physiological and genetic analyses of peptide signaling in Drosophila.     

Searching for pattern and mutation in the Drosophila genome with a P-lacZ vector

A P-element vector has been constructed and used to generate lines of flies with single autosomal P-element insertions. The lines were analyzed in two ways: (1) the identification of cis-acting patterning information within the Drosophila genome, as revealed by a lacZ reporter gene within the P element, and (2) the isolation of lethal mutations. We examined 3768 independent lines for the expression of lacZ in embryos and looked among these lines for lethal mutations affecting embryonic neurogenesis. This type of screen appears to be an effective way to find new loci that may play a role in the development of the Drosophila nervous system.     

Molecular characterization of two natural hotspots in the Drosophila buzzatii genome induced by transposon insertions

Transposable elements (TEs) have been implicated in the generation of genetic rearrangements, but their potential to mediate changes in the organization and architecture of host genomes could be even greater than previously thought. Here, we describe the naturally occurring structural and nucleotide variation around two TE insertions in the genome of Drosophila buzzatii. The studied regions correspond to the breakpoints of a widespread chromosomal inversion generated by ectopic recombination between oppositely oriented copies of a TE named Galileo. A detailed molecular analysis by Southern hybridization, PCR amplification, and DNA sequencing of 7.1 kb surrounding the inversion breakpoints in 39 D. buzzatii lines revealed an unprecedented degree of restructuring, consisting of 22 insertions of ten previously undescribed TEs, 13 deletions, 1 duplication, and 1 small inversion. All of these alterations occurred exclusively in inverted chromosomes and appear to have accumulated after the insertion of the Galileo elements, within or close to them. The nucleotide variation at the studied regions is six times lower in inverted than in noninverted chromosomes, suggesting that most of the observed changes originated in only 84,000 years. Galileo elements thus seemed to promote the transformation of these, otherwise normal, chromosomal regions in genetically unstable hotspots and highly efficient traps for transposon insertions. The particular features of two new Galileo copies found indicate that this TE belongs to the Foldback family. Together, our results strengthen the importance of TEs, and especially DNA transposons, as inducers of genome plasticity in evolution.     

B-ZIP proteins encoded by the Drosophila genome: evaluation of potential dimerization partners

The basic region-leucine zipper (B-ZIP) (bZIP) protein motif dimerizes to bind specific DNA sequences. We have identified 27 B-ZIP proteins in the recently sequenced Drosophila melanogaster genome. The dimerization specificity of these 27 B-ZIP proteins was evaluated using two structural criteria: (1) the presence of attractive or repulsive interhelical g<-->e' electrostatic interactions and (2) the presence of polar or charged amino acids in the 'a' and 'd' positions of the hydrophobic interface. None of the B-ZIP proteins contain only aliphatic amino acids in the'a' and 'd' position. Only six of the Drosophila B-ZIP proteins contain a "canonical" hydrophobic interface like the yeast GCN4, and the mammalian JUN, ATF2, CREB, C/EBP, and PAR leucine zippers, characterized by asparagine in the second 'a' position. Twelve leucine zippers contain polar amino acids in the first, third, and fourth 'a' positions. Circular dichroism spectroscopy, used to monitor thermal denaturations of a heterodimerizing leucine zipper system containing either valine (V) or asparagine (N) in the 'a' position, indicates that the V-N interaction is 2.3 kcal/mole less stable than an N-N interaction and 5.3 kcal/mole less stable than a V-V interaction. Thus, we propose that the presence of polar amino acids in novel positions of the 'a' position of Drosophila B-ZIP proteins has led to leucine zippers that homodimerize rather than heterodimerize.     

Phylogenetic structure in African HIV-1 subtype C revealed by selective sequential pruning

Subtype C is the most prevalent clade in the HIV-1 pandemic. Previous studies suggested that African HIV-1 subtype C lacks a well-defined phylogenetic structure. Here we show that, by sequential pruning of ambiguously positioned taxa, a well-defined intrasubtype C phylogenetic structure becomes apparent, with 52% African HIV-1 subtype C isolates analyzed in envelope sequences branching within 11 clusters, also supported in a tree of full-length genomes, and all with geographical associations. Among 46 viruses recently transmitted in South Africa, 70% branched within 7 clusters (41% in the largest one) and 15% additional isolates were intercluster recombinants. Choice of the outgroup sequence and inclusion of intrasubtype recombinant viruses in the analyses could greatly affect support of clusters. The identification of clusters comprising a large proportion of African HIV-1 subtype C viruses may have implications for the design of vaccines intended for use in areas where subtype C is prevalent.