Complete genome sequence and transcriptomics analyses reveal pigment biosynthesis and regulatory mechanisms in an industrial strain, Monascus purpureus YY-1.

Yue Yang,Liangcheng Du,Xiaozhen Cheng,Bin Liang,Shuo Wang,Xinjun Du,Lei Wang,Ping Li,Bin Liu,Di Huang

doi:10.1038/srep08331

Abstract

Monascus has been used to produce natural colorants and food supplements for more than one thousand years, and approximately more than one billion people eat Monascus-fermented products during their daily life. In this study, using next-generation sequencing and optical mapping approaches, a 24.1-Mb complete genome of an industrial strain, Monascus purpureus YY-1, was obtained. This genome consists of eight chromosomes and 7,491 genes. Phylogenetic analysis at the genome level provides convincing evidence for the evolutionary position of M. purpureus. We provide the first comprehensive prediction of the biosynthetic pathway for Monascus pigment. Comparative genomic analyses show that the genome of M. purpureus is 13.6–40% smaller than those of closely related filamentous fungi and has undergone significant gene losses, most of which likely occurred during its specialized adaptation to starch-based foods. Comparative transcriptome analysis reveals that carbon starvation stress, resulting from the use of relatively low-quality carbon sources, contributes to the high yield of pigments by repressing central carbon metabolism and augmenting the acetyl-CoA pool. Our work provides important insights into the evolution of this economically important fungus and lays a foundation for future genetic manipulation and engineering of this strain.

Highlights

Complete genome sequence and transcriptomics analyses reveal pigment biosynthesis and regulatory mechanisms in an industrial strain, Monascus purpureus YY-1
A potential gene cluster involved in the synthesis of pigments was identified in M. pilosus, and a homolog of the key polyketide synthase (PKS) gene was experimentally identified by mutagenesis in M. purpureus[13]
The identities of several other steps and related enzymes involved in pigment biosynthesis are still unclear or remain controversial, and this situation inhibits the construction of industrial strains with better pigment-producing abilities

Summary

Introduction

Complete genome sequence and transcriptomics analyses reveal pigment biosynthesis and regulatory mechanisms in an industrial strain, Monascus purpureus YY-1. Monascus has been used to produce natural colorants and food supplements for more than one thousand years, and approximately more than one billion people eat Monascus-fermented products during their daily life. In this study, using next-generation sequencing and optical mapping approaches, a 24.1-Mb complete genome of an industrial strain, Monascus purpureus YY-1, was obtained. This genome consists of eight chromosomes and 7,491 genes. Monascus has been used in food production for more than one thousand years, further investigations of the regulatory mechanisms of pigment biosynthesis and the optimization of fermentation conditions are required. The elucidation of the global regulatory network that controls pigment biosynthesis in Monascus will greatly aid such efforts in industry

Methods

Results

Conclusion