Abstract
Next-Generation-Sequencing is advantageous because of its much higher data throughput and much lower cost compared with the traditional Sanger method. However, NGS reads are shorter than Sanger reads, making de novo genome assembly very challenging. Because genome assembly is essential for all downstream biological studies, great efforts have been made to enhance the completeness of genome assembly, which requires the presence of long reads or long distance information. To improve de novo genome assembly, we develop a computational program, ARF-PE, to increase the length of Illumina reads. ARF-PE takes as input Illumina paired-end (PE) reads and recovers the original DNA fragments from which two ends the paired reads are obtained. On the PE data of four bacteria, ARF-PE recovered >87% of the DNA fragments and achieved >98% of perfect DNA fragment recovery. Using Velvet, SOAPdenovo, Newbler, and CABOG, we evaluated the benefits of recovered DNA fragments to genome assembly. For all four bacteria, the recovered DNA fragments increased the assembly contiguity. For example, the N50 lengths of the P. brasiliensis contigs assembled by SOAPdenovo and Newbler increased from 80,524 bp to 166,573 bp and from 80,655 bp to 193,388 bp, respectively. ARF-PE also increased assembly accuracy in many cases. On the PE data of two fungi and a human chromosome, ARF-PE doubled and tripled the N50 length. However, the assembly accuracies dropped, but still remained >91%. In general, ARF-PE can increase both assembly contiguity and accuracy for bacterial genomes. For complex eukaryotic genomes, ARF-PE is promising because it raises assembly contiguity. But future error correction is needed for ARF-PE to also increase the assembly accuracy. ARF-PE is freely available at http://140.116.235.124/~tliu/arf-pe/.
Highlights
Next-generation-sequencing has transformed recent biological studies [1], including genome assembly
We were left with four bacterial species: C. marinum, P. brasiliensis, S. smaragdinae, and Streptomyces violaceusniger (S. vio)
We found that the recovered DNA fragments lowered the assembly accuracy, but they increased the N50 length even greater, resulting in a larger N50 length
Summary
Next-generation-sequencing has transformed recent biological studies [1], including genome assembly. Compared with the traditional Sanger method [2], the throughput of NGS data is much higher and the cost is much lower [3]. Because of these advantages, the number of genome projects has been increasing significantly [4]. One big challenge stems from the short length of NGS reads. The new version of 454 machine can generate ,800 bp reads, only parts of the data reach this length. Short read length is problematic with the presence of repetitive sequences (called repeats) in genomes [6]. It is rare that current assemblers can assemble NGS reads into one complete genome at one shot even for small microbial genomes
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