Background : Lycoris radiata (L. radiata), which belongs to Amaryllidaceae family, is native to Northeast Asia including Korea, Japan, and China. It is known for its high ornamental and medicinal values. Extensive research has been conducted in a several fields, including molecular biology, morphology, pharmacology, physiology, palynology, and chromosomal biology. The plant is notable for its various biological activities, including anti-cancer, anti-malarial, anti-microbial, reduction in blood pressure, anti-inflammatory, cytotoxicity, and neuroprotective effects. Methods and Results : The results of studies conducted in duplicate revealed the presence of a total of 325,609 and 404,019 unigenes, acquired from 9,913,869,968 and 10,162,653,038 raw reads, respectively, after trimming the raw reads using CutAdapt, assembly using Trinity package, and clustering using CD-Hit-EST. The resulting unigenes were annotated based on the NCBI Non-redundant protein database, as L. radiata is genetically closer to Elaeis guineensis and Phoenix dactylifera. The unigenes of L. radiata were clustered into three major categories: biological processes, cellular components, and molecular functions, with 51 functional sections. A large number of unigenes (203,157 and 224,813 from replicates 1 and 2, respectively) were categorized in the biological process cluster, followed by the cellular component cluster, and the molecular function cluster. With respect to the biological process category, the unigenes were assigned to 23 functional sections. The majority of unigenes were involved in cellular processes. Among the unigenes clustered as the cellular component with 14 sections, most genes were associated with the cell and cell parts. Furthermore, 78,017 and 88,817 unigenes, respectively, matched the molecular function cluster with 14 sections, of which most unigenes were related to binding and catalytic activity. Conclusion : This study provides functional information of L. radiata and highlights the use of the Illumina platform for transcriptome research.

Background : Momordica charantia L. (M. charantia) is a member of the family Cucurbitaceae, used as a medicine herb in traditional medicine. In this study, we present the sequencing, de novo assembly and analysis of the transcriptome of M. charantia and provide a global description of relationship between putative phenylpropanoid and flavonoid biosynthesis genes and alteration of phenylpropanoid and flavonoid content during different organs and plantlet of M. charantia. Methods and Results : The transcriptome of M. charantia was constructed by using an Illumina Nexteseq500 sequencing system. Out of 68,073,862 total reads, approximately 88,703 unigenes were identified with a length of 898 bp. Alternatively, transcriptomic data, 10cDNAs (McPAL, McC4H, Mc4CL, McCOMT, McCHS, McCHI, McF3H, McFLS, McDFR and Mc3GT) encoded phenylpropanoid and flavonoid biosynthetic genes. The expression levels and the accumulation of trans-cinnamic acid, benzoic acid, 4-hydroxyvbenzoic acid, p-coumaric acid, chlorogenic acid, caffeic acid, catechin hydrate, ferulic acid, and rutin were investigated in different organs and plantlets. Mainly, phenylpropanoids and flavonoids accumulated in leaves and flowers, whereas low levels accumulated in roots. Collectively, these results indicate that the putative McPAL, McC4H, McCOMT, McFLS, and Mc3GT might be key factors for controlling phenylpropanoid and flavonoid contents in M. charantia. Conclusion : In this study, we present the sequencing, de novo assembly and analysis of the transcriptome of M. charantia. We also compared gene expression and compound analysis of phenylpropanoid and flavonoid in different organs and plantlet of M. charantia. These results indicate that McPAL, McC4H, McCOMT, McFLS, and Mc3GT are key regulators of phenylpropanoid and flavonoid accumulation in M. charantia

Gibberellic acid (GA) is a well-characterized plant hormone, which plays a critical role in various plant growth and development. including stem elongation, floral indcution and seed development. GA is known to cause enlargement of ripening fruits and, especially in grapevines, GA shows a unique function: the induction of seedlessness in seeded grape varieties. However, despite extensive previous studies about GA, there has been no clear verification of the mechanism that induces seedlessness in grapes. To understand how GA treatment results in artificial parthenocarpy of seeded grapes at molecular levels, we analyzed transcriptional changes in seeded grapes with and without GA application in various inflorescence developmental stages using RNA-seq. At 14 days before flowering (DBF), seeded grapes were treated with 100 ppm GA and clusters were collected at three developmental stages: 7 DBF, full bloom, and 5 days after flowering (DAF). Of a total of 28,974 genes that were mapped to grape genome reference sequences, 7,013 and 9,064 genes were up- and down-regulated, respectively, in the GA-treated grape as compared to the non-GA-treated control at 7 DBF, full bloom, and 5 DAF. Clustering analysis revealed that these genes could be grouped into 9 clusters with different expression patterns. We also carried out functional annotation based on gene ontology categories. There were significant differences in the expression of the GA and auxin-related gene families. These findings expand our understanding of the complex molecular and cellular mechanisms of GA-induced parthenocarpy of grapes and provide a foundation for future studies on seed development in grapevines.