To
develop the versatile methodology for genome mining of mushroom
metabolites, we examined the production of bioactive diterpenes erinacines
using genomic DNA sequences. In this report, we initially identified
high expression loci (hot spots) in Aspergillus oryzae by sequencing the genomic DNAs from highly yielding transformants
which were obtained in our previous biosynthetic studies. Genome editing
knock-in of all erinacine biosynthetic genes directly to the hot spot
showed that A. oryzae correctly spliced more than
90% of the introns in the mushroom genomic DNA gene sequences. Then,
we reconstituted the erinacine biosynthetic gene cluster using two
rounds of knock-in of the cDNAs and newly developed repeatable genetic
engineering by plasmid recycling. At 100% transformation rate, we
obtained a transformant that successfully produced erinacine Q and
its intermediates. In this study, we elucidated a biosynthetic pathway
of erinacines involving functionally unique hydroxylation supported
by dehydrogenase EriH and xylose-specific glycosylation by introducing
plant genes for supplying UDP-xylose. Our newly developed hot spot
knock-in and plasmid recycling allowed us to avoid a time-consuming
screening process and to use unlimited introduction of biosynthetic
genes due to marker-free genome editing.