Project description:For many decades Indigenous people, including Native Americans and Aboriginal Australians, have fought for their return of their ancient people. By sequencing ten ancient nuclear genomes of Aboriginal Australians and 27 mitogenomes from ancient pre-European Aboriginal Australians (up to 1,540 yr BP) of known provenance we demonstrate the feasibility of successfully identifying the geographic origins of unprovenanced ancestral remains using genomic methods.
Project description:It remains challenging to study the viability and metabolic activity of microorganisms buried in ancient permafrost. We coupled aspartic acid racemization assay with metaproteomics to constraint the microbial activity of indigenous microbial community entrappped in permafrost sediment over 100 kyr ago.
Project description:Microarray based CGH was conducted over a group of 29 strains of S. Enteritidis spanning different epidemiological periods in Uruguay, plus 6 other S. Enteritidis strains isolated from distant geographical regions. We also included 9 Salmonella enterica strains of other serovars isolated in Uruguay. A S. Enteritidis dispensable genome of 233 chromosomal genes and high extent of variation in virulence plasmid was found. Strains isolated before the epidemic show the highest genomic differences as compared with the PT4 reference strain. Comparison with the gene content of other serovars demonstrate extensive horizontal gene transfer between circulating strains beyond serovar definition. Our results show that the epidemic of S Enteritidis in Uruguay was produced by the introduction of strains closely related to PT4, and corroborate the extensive genetic homogeneity among S. Enteritidis isolates worldwide. Phage SE14 emerges as the only specific region for S. Enteritidis. Genetic differences detected in pre-epidemic strains, mainly associated with the absence of phage SE20, suggest that genetic features encoded in this phage may be related to particular epidemiological behavior.
Project description:Gene order, or microsynteny, is generally thought not to be conserved across metazoan phyla. Only a handful of exceptions, typically of tandemly duplicated genes such as Hox genes, have been discovered. Here, we performed a systematic survey for microsynteny conservation in 17 genomes and identified nearly 600 pairs of unrelated genes that have remained together across over 600 million years of evolution. Using multiple genome-wide resources, including several genomic features, epigenetic marks, sequence conservation and microarray expression data, we provide extensive evidence that many of these ancient microsyntenic arrangements have been conserved in order to preserve either (i) the coordinated transcription of neighboring genes, or (ii) Genomic Regulatory Blocks (GRBs), in which transcriptional enhancers controlling key developmental genes are contained within nearby “bystander” genes. In addition, we generated ChIP-seq data for key histone modifications in zebrafish embryos to further investigate putative GRBs in embryonic development. Finally, using chromosome conformation capture (3C) assays and stable transgenic experiments, we demonstrate that enhancers within bystander genes drive the expression of genes such as Otx and Islet, critical regulators of central nervous system development across bilaterians. These results show that ancient genomic associations are far more common in modern metazoans than previously thought – likely involving over 12% of the ancestral bilaterian genome – and that cis-regulatory constraints have played a major role in conserving the architecture of metazoan genomes. ChIP-seq H3K27me3 of 24hpf zebrafish embryos
Project description:CNV plays an important role in the chicken genomic studies,it is imperative need to investigate the extent and pattern of CNVs using array comparative genomic hybridization (aCGH) in chinese chicken breeds for future studies associating phenotype to genome architecture. we describe systematic and genome-wide analysis of CNVs loci in five Chinese indigenous chicken breeds were evaluated by aCGH.
Project description:Affymetrix single nucleotide polymorphism (SNP) array data were used to study genes that underlie human adaptation to climatic stress, with a focus on genetic changes that lead to long-term cold tolerance. Siberia provides the best opportunity to investigate the genetic mechanisms of cold resistance because of the long-term ancestry of indigenous populations in some of the coldest climates on earth. While much of northern Europe was under ice throughout the last glacial period, Siberia remained relatively ice free, and archaeological evidence suggests that people inhabited this region for more than 40,000 years. We gathered SNP data from ~200 individuals from 15 indigenous Siberian populations that inhabit a range of arctic climates and compare their patterns of genetic variation with those from other world populations from warmer climates.Particular attention is paid to regions containing genes that have been previously implicated in cold adaptation or that function in known pathways connected to energy metabolism or cold adapted phenotypes (e.g., those involved in basal metabolic rate and brown adipose tissue function).
Project description:Gene order, or microsynteny, is generally thought not to be conserved across metazoan phyla. Only a handful of exceptions, typically of tandemly duplicated genes such as Hox genes, have been discovered. Here, we performed a systematic survey for microsynteny conservation in 17 genomes and identified nearly 600 pairs of unrelated genes that have remained together across over 600 million years of evolution. Using multiple genome-wide resources, including several genomic features, epigenetic marks, sequence conservation and microarray expression data, we provide extensive evidence that many of these ancient microsyntenic arrangements have been conserved in order to preserve either (i) the coordinated transcription of neighboring genes, or (ii) Genomic Regulatory Blocks (GRBs), in which transcriptional enhancers controlling key developmental genes are contained within nearby “bystander” genes. In addition, we generated ChIP-seq data for key histone modifications in zebrafish embryos to further investigate putative GRBs in embryonic development. Finally, using chromosome conformation capture (3C) assays and stable transgenic experiments, we demonstrate that enhancers within bystander genes drive the expression of genes such as Otx and Islet, critical regulators of central nervous system development across bilaterians. These results show that ancient genomic associations are far more common in modern metazoans than previously thought – likely involving over 12% of the ancestral bilaterian genome – and that cis-regulatory constraints have played a major role in conserving the architecture of metazoan genomes.