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Single-Molecule Real-Time Sequencing Combined with Optical Mapping Yields Completely Finished Fungal Genome.

Luigi FainoMichael F SeidlErwin DatemaGrardy C M van den BergAntoine JanssenAlexander H J WittenbergBart P H J Thomma
Published in: mBio (2015)
Studying whole-genome sequences has become an important aspect of biological research. The advent of next-generation sequencing (NGS) technologies has nowadays brought genomic science within reach of most research laboratories, including those that study nonmodel organisms. However, most genome sequencing initiatives typically yield (highly) fragmented genome assemblies. Nevertheless, considerable relevant information related to genome structure and evolution is likely hidden in those nonassembled regions. Here, we investigated a diverse set of strategies to obtain gapless genome assemblies, using the genome of a typical ascomycete fungus as the template. Eventually, we were able to show that a combination of PacBio-generated long reads and optical mapping yields a gapless telomere-to-telomere genome assembly, allowing in-depth genome analyses to facilitate functional studies into an organism's biology.
Keyphrases
  • genome wide
  • single molecule
  • high resolution
  • gene expression
  • single cell
  • dna methylation
  • atomic force microscopy
  • mass spectrometry
  • high speed
  • social media
  • high density