A 2.91-billion base pair (bp) consensus sequence of the euchromatic portion of the human genome was generated by the whole-genome shotgun sequencing method. The 14.8-billion bp DNA sequence was generated over 9 months from 27,271,853 high-quality sequence reads (5.11-fold coverage of the genome) from both ends of plasmid clones made from the DNA of five individuals. Two assembly strategies—a whole-genome assembly and a regional chromosome assembly—were used, each combining sequence data from Celera and the publicly funded genome effort. The public data were shredded into 550-bp segments to create a 2.9-fold coverage of those genome regions that had been sequenced, without including biases inherent in the cloning and assembly procedure used by the publicly funded group. This brought the effective coverage in the assemblies to eightfold, reducing the number and size of gaps in the final assembly over what would be obtained with 5.11-fold coverage. The two assembly strategies yielded very similar results that largely agree with independent mapping data. The assemblies effectively cover the euchromatic regions of the human chromosomes. More than 90% of the genome is in scaffold assemblies of 100,000 bp or more, and 25% of the genome is in scaffolds of 10 million bp or larger. Analysis of the genome sequence revealed 26,588 protein-encoding transcripts for which there was strong corroborating evidence and an additional ∼12,000 computationally derived genes with mouse matches or other weak supporting evidence. Although gene-dense clusters are obvious, almost half the genes are dispersed in low G+C sequence separated by large tracts of apparently noncoding sequence. Only 1.1% of the genome is spanned by exons, whereas 24% is in introns, with 75% of the genome being intergenic DNA. Duplications of segmental blocks, ranging in size up to chromosomal lengths, are abundant throughout the genome and reveal a complex evolutionary history. Comparative genomic analysis indicates vertebrate expansions of genes associated with neuronal function, with tissue-specific developmental regulation, and with the hemostasis and immune systems. DNA sequence comparisons between the consensus sequence and publicly funded genome data provided locations of 2.1 million single-nucleotide polymorphisms (SNPs). A random pair of human haploid genomes differed at a rate of 1 bp per 1250 on average, but there was marked heterogeneity in the level of polymorphism across the genome. Less than 1% of all SNPs resulted in variation in proteins, but the task of determining which SNPs have functional consequences remains an open challenge.
The fly Drosophila melanogaster is one of the most intensively studied organisms in biology and serves as a model system for the investigation of many developmental and cellular processes common to higher eukaryotes, including humans. We have determined the nucleotide sequence of nearly all of the ∼120-megabase euchromatic portion of the Drosophila genome using a whole-genome shotgun sequencing strategy supported by extensive clone-based sequence and a high-quality bacterial artificial chromosome physical map. Efforts are under way to close the remaining gaps; however, the sequence is of sufficient accuracy and contiguity to be declared substantially complete and to support an initial analysis of genome structure and preliminary gene annotation and interpretation. The genome encodes ∼13,600 genes, somewhat fewer than the smaller Caenorhabditis elegans genome, but with comparable functional diversity.
We have synthesized a 582,970-base pair Mycoplasma genitalium genome. This synthetic genome, named M. genitalium JCVI-1.0, contains all the genes of wild-type M. genitalium G37 except MG408, which was disrupted by an antibiotic marker to block pathogenicity and to allow for selection. To identify the genome as synthetic, we inserted "watermarks" at intergenic sites known to tolerate transposon insertions. Overlapping "cassettes" of 5 to 7 kilobases (kb), assembled from chemically synthesized oligonucleotides, were joined by in vitro recombination to produce intermediate assemblies of approximately 24 kb, 72 kb ("1/8 genome"), and 144 kb ("1/4 genome"), which were all cloned as bacterial artificial chromosomes in Escherichia coli. Most of these intermediate clones were sequenced, and clones of all four 1/4 genomes with the correct sequence were identified. The complete synthetic genome was assembled by transformation-associated recombination cloning in the yeast Saccharomyces cerevisiae, then isolated and sequenced. A clone with the correct sequence was identified. The methods described here will be generally useful for constructing large DNA molecules from chemically synthesized pieces and also from combinations of natural and synthetic DNA segments.
We previously reported assembly and cloning of the synthetic Mycoplasma genitalium JCVI-1.0 genome in the yeast Saccharomyces cerevisiae by recombination of six overlapping DNA fragments to produce a 592-kb circle. Here we extend this approach by demonstrating assembly of the synthetic genome from 25 overlapping fragments in a single step. The use of yeast recombination greatly simplifies the assembly of large DNA molecules from both synthetic and natural fragments.in vivo DNA assembly ͉ genome synthesis ͉ combinatorial assembly ͉ yeast transformation ͉ Mycoplasma genitalium ͉ synthetic biology Y east has long been considered a genetically tractable organism because of its ability to take up and recombine DNA fragments. More than 30 years ago, Hinnen et al. (1) reported the restoration of leucine biosynthesis in Saccharomyces cerevisiae by transformation of a leu2 -strain to LEU2ϩ using a method involving spheroplasts, CaCl 2 , and PEG. Soon after, Orr-Weaver et al. (2) reported mechanistic studies demonstrating that DNA molecules taken up during yeast transformation can integrate into yeast chromosomes through homologous recombination, and that the ends of the linear-transforming DNA are highly recombinogenic and react directly with homologous chromosomal sequences, whereas circular plasmids carrying yeast sequences integrate by a single crossover and only at low frequency. Subsequently, yeast transformation has become an indispensable tool in yeast genetics.Yeast recombination has since been applied to the construction of plasmids and yeast artificial chromosomes (YACs). In 1987, Ma et al. (3) constructed plasmids from two cotransformed DNA fragments containing homologous regions. In another process, called linker-mediated assembly, any DNA sequence can be joined to a vector DNA using short synthetic linkers that bridge the ends (4, 5). Similarly, four or five overlapping DNA pieces can be assembled and joined to vector DNA (4, 6, 7). This work demonstrated that yeast cells can take up multiple pieces of DNA, and that homologous yeast recombination is sufficiently efficient to correctly assemble the pieces into a single recombinant molecule.The limitations of assembly methods in yeast remain unknown. We recently assembled an entire synthetic M. genitalium genome using a combination of in vitro enzymatic recombination in early stages and in vivo yeast recombination in the final stage to produce the complete genome (8). In the first stage, overlapping Ϸ6-kb DNA cassettes were joined four at a time to form 25 Ϸ24-kb A-series assemblies. Three A-series assemblies were then joined to make 1/8 genome Ϸ72-kb B-series assemblies, and then two Bseries assemblies were assembled to make each of the Ϸ145-kb quarter-genome C-series assemblies. We accomplished the final assembly in yeast using three quarter-genome fragments and a fourth quarter fragment that had been cleaved by a restriction enzyme to provide a site for insertion of the vector DNA. Thus, some individual yeast cells have the capacity to simultaneously tak...
The high degree of similarity between the mouse and human genomes is demonstrated through analysis of the sequence of mouse chromosome 16 (Mmu 16), which was obtained as part of a whole-genome shotgun assembly of the mouse genome. The mouse genome is about 10% smaller than the human genome, owing to a lower repetitive DNA content. Comparison of the structure and protein-coding potential of Mmu 16 with that of the homologous segments of the human genome identifies regions of conserved synteny with human chromosomes (Hsa) 3, 8, 12, 16, 21, and 22. Gene content and order are highly conserved between Mmu 16 and the syntenic blocks of the human genome. Of the 731 predicted genes on Mmu 16, 509 align with orthologs on the corresponding portions of the human genome, 44 are likely paralogous to these genes, and 164 genes have homologs elsewhere in the human genome; there are 14 genes for which we could find no human counterpart.
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