The Genome of the Korean Island-Originated Perilla citriodora 'Jeju17' Sheds Light on Its Environmental Adaptation and Fatty Acid and Lipid Production Pathways.

Perilla is a key component of Korean food. It contains several plant-specialized metabolites that provide medical benefits. In response to an increased interest in healthy supplement food from the public, people are focusing on the properties of Perilla. Nevertheless, unlike rice and soybeans, there are few studies based on molecular genetics on Perilla, so it is difficult to systematically study the molecular breed. The wild Perilla, Perilla citriodora 'Jeju17', was identified a decade ago on the Korean island of Jeju. Using short-reads, long-reads, and Hi-C, a chromosome-scale genome spanning 676 Mbp, with high contiguity, was assembled. Aligning the 'Jeju17' genome to the 'PC002' Chinese species revealed significant collinearity with respect to the total length. A total of 31,769 coding sequences were predicted, among which 3331 were 'Jeju17'-specific. Gene enrichment of the species-specific gene repertoire highlighted environment adaptation, fatty acid metabolism, and plant-specialized metabolite biosynthesis. Using a homology-based approach, genes involved in fatty acid and lipid triacylglycerol biosynthesis were identified. A total of 22 fatty acid desaturases were found and comprehensively characterized. Expression of the FAD genes in 'Jeju17' was examined at the seed level, and hormone signaling factors were identified. The results showed that the expression of FAD genes in 'Jeju17' at the seed level was high 25 days after flowering, and their responses of hormones and stress were mainly associated with hormone signal transduction and abiotic stress via cis-elements patterns. This study presents a chromosome-level genome assembly of P. citriodora 'Jeju17', the first wild Perilla to be sequenced from the Korean island of Jeju. The analyses provided can be useful in designing ALA-enhanced Perilla genotypes in the future.

Advances in Understanding the Genetic Basis of Fatty Acids Biosynthesis in Perilla: An Update.

Perilla, also termed as purple mint, Chinese basil, or Perilla mint, is a flavoring herb widely used in East Asia. Both crude oil and essential oil are employed for consumption as well as industrial purposes. Fatty acids (FAs) biosynthesis and oil body assemblies in Perilla have been extensively investigated over the last three decades. Recent advances have been made in order to reveal the enzymes involved in the fatty acid biosynthesis in Perilla. Among those fatty acids, alpha-linolenic acid retained the attention of scientists mainly due to its medicinal and nutraceutical properties. Lipids synthesis in Perilla exhibited similarities with Arabidopsis thaliana lipids' pathway. The homologous coding genes for polyunsaturated fatty acid desaturases, transcription factors, and major acyl-related enzymes have been found in Perilla via de novo transcriptome profiling, genome-wide association study, and in silico whole-genome screening. The identified genes covered de novo fatty acid synthesis, acyl-CoA dependent Kennedy pathway, acyl-CoA independent pathway, Triacylglycerols (TAGs) assembly, and acyl editing of phosphatidylcholine. In addition to the enzymes, transcription factors including WRINKLED, FUSCA3, LEAFY COTYLEDON1, and ABSCISIC ACID INSENSITIVE3 have been suggested. Meanwhile, the epigenome aspect impacting the transcriptional regulation of FAs is still unclear and might require more attention from the scientific community. This review mainly outlines the identification of the key gene master players involved in Perilla FAs biosynthesis and TAGs assembly that have been identified in recent years. With the recent advances in genomics resources regarding this orphan crop, we provided an updated overview of the recent contributions into the comprehension of the genetic background of fatty acid biosynthesis. The provided resources can be useful for further usage in oil-bioengineering and the design of alpha-linolenic acid-boosted Perilla genotypes in the future.

The complete chloroplast genome of Adenophora triphylla (Asterales: Campanulaceae).

Adenophora triphylla (A. triphylla) is an important oriental herb belonging to the Campanulaceae family. A. triphylla complete chloroplast genome is composed of 239,431 bp, which form a large single-copy region (LSC, 178,906 bp), a small single-copy region (SSC, 55,819 bp), and 2 inverted repeats (IRs, 2,353 bp). There are 108 genes annotated, including 74 protein-coding genes, 4 ribosomal RNA genes, and 30 transfer RNA genes. Phylogeny indicates that A. triphylla was belong to Adenophora genus as a sister group and most closely related to Adenophora divaricate.

Transcriptome data for tissue-specific genes in four reproductive organs at three developmental stages of micro-tom tomato.

Tomato belongs to the Solanaceae family of plants. It is a diploid plant with 12 chromosomes. Previous studies have reported that its genome size is 950 MB with 35,000 protein-coding genes. Micro-Tom Tomato is a miniature dwarf determinate tomato cultivar. It has a small-sized genome, a short lifecycle, and a short seed-setting under fluorescent light. These features are similar to those of Arabidopsis. Consequently, Micro-Tom Tomato is considered as a model cultivar of tomato (Solanum lycopersicum) suitable for research. We sequenced its transcriptomes to identify tissue-specific gene candidate profiles in different plant tissues (petals, sepals, pistils, and stamens) at developmental stages.

Molecular marker database for efficient use in agricultural breeding programs.

UNLABELLED: The National Agricultural Biotechnology Information Center (NABIC) constructed a web-based molecular marker database to provide information about 7,847 sequence-tagged site (STS) markers identified in the 11 species using a next generation sequencing (NGS) technologies. The database consists of three major functional categories: keyword search, detailed viewer and download function. The molecular marker annotation table provides detailed information such as ownership information, basic information, and STS-related characterization information. AVAILABILITY: The database is available for free at http://nabic.rda.go.kr/Molecularmarker.