A recent study has assembled a gap-free genome for Mentha suaveolens, providing new insights into its genetic structure and terpenoid diversification. The research highlights the unique composition of volatile compounds, particularly piperitenone oxide, and identifies key genetic variations affecting its biosynthesis. These findings enhance our understanding of Mentha's medicinal properties and facilitate targeted breeding for improved traits.
Mentha suaveolens, commonly known as pineapple mint, is valued for its distinct aroma and medicinal properties, which are attributed to its essential oils. Despite its importance, understanding the genetic basis of these traits has been challenging due to the complexity of the Mentha genome, characterized by high heterozygosity and numerous structural variations. A comprehensive study of the Mentha genome was essential to uncover the genetic factors influencing its unique characteristics.
Researchers from the Chengdu University of Traditional Chinese Medicine, in collaboration with several other institutions, published a study (DOI: 10.1093/hr/uhae022) in the journal Horticulture Research on January 17, 2024. The team has successfully assembled a haplotype-resolved, gap-free genome of Mentha suaveolens, also known as pineapple mint. Utilizing advanced sequencing technologies, this study sheds light on the genetic diversity and structural variations within the genome, providing a valuable resource for future genetic and breeding research.
The study presents the first high-quality, haplotype-resolved genome assembly for Mentha suaveolens, with a genome size of 414.3 Mb and 31,251 coding genes. By integrating data from various sequencing platforms, the researchers resolved two complete haplotypic assemblies, each nearly fully annotated for telomeres and centromeres. Notably, the analysis revealed 41,135 structural variations, including deletions, insertions, duplications, and translocations, many of which impact genes involved in terpenoid biosynthesis. One significant finding is the predominance of piperitenone oxide among the volatile compounds produced by M. suaveolens, as opposed to menthol, which is more common in other Mentha species. The study identified three genes encoding isopiperitenone reductase (ISPR), a key enzyme in menthol biosynthesis, but found that their low transcription levels likely lead to the accumulation of piperitenone oxide instead.
Dr. Chi Song, one of the leading researchers, stated, "The completion of the gap-free genome for Mentha suaveolens represents a significant milestone in plant genomics. This comprehensive genetic map provides a foundation for exploring the molecular mechanisms underlying the unique properties of pineapple mint, which could lead to innovative applications in medicine and agriculture."
The gap-free genome assembly of Mentha suaveolens paves the way for genetic research and breeding to enhance its medicinal and aromatic qualities. Understanding the genetic basis of terpenoid biosynthesis enables targeted strategies to optimize valuable compounds like piperitenone oxide. This research advances plant genomics and has significant potential to improve the cultivation and commercial value of Mentha species.