Differential Expression of Amanitin Biosynthetic Genes and Novel Cyclic Peptides in

Overview

Journal J Fungi (Basel)

Date 2021 Jun 2

PMID 34069263

Citations 2

Authors

Yunjiao Luli

Shengwen Zhou

Xuan Li

Zuohong Chen

Zhuliang Yang

Hong Luo

Affiliations

Soon will be listed here.

Abstract

is a basal species of lethal and intrigues the field because it does not produce discernable α-amanitin when inspected by High Performance Liquid Chromatography (HPLC), which sets it apart from all known amanitin-producing (lethal) species. In order to study the underlining genetic basis of the phenotype, we sequenced this species through PacBio and Illumina RNA-Seq platforms. In total, 17 genes of the "" family (named after the first five amino acid residues of the precursor peptides) were found in the genome and 11 of them were expressed at the transcription level. The expression pattern was not even but in a differential fashion: two of the s were highly expressed (FPKM value > 100), while the majority were expressed at low levels (FPKM value < 1). Prolyl oligopeptidease B (POPB) is the key enzyme in the amanitin biosynthetic pathway, and high expression of this enzyme was also discovered (FPKM value > 100). The two s with highest transcription further translated into two novel cyclic peptides, the structure of which is distinctive from all known cyclic peptides. The result illustrates the correlation between the expression and the final peptide products. In contrast to previous HPLC result, the genome of harbors α-amanitin genes (three copies), but the product was in trace amount indicated by MS. Overall, transcription of s encoding major toxins (α-amanitin, β-amanitin, phallacidin and phalloidin) were low, showing that these toxins were not actively synthesized at the stage. Collectively, our results indicate that the amanitin biosynthetic pathway is highly active at the mature fruiting body stage in , and due to the differential expression of genes, the pathway produces only a few cyclic peptides at the time.

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