Your search keyword '"Terpene synthases"' showing total 5 results

1. Combined sensory, volatilome and transcriptome analyses identify a limonene terpene synthase as a major contributor to the characteristic aroma of a Coffea arabica L. specialty coffee.

Author

Marie, Lison, Breitler, Jean-Christophe, Bamogo, Pingdwende Kader Aziz, Bordeaux, Mélanie, Lacombe, Séverine, Rios, Maëlle, Lebrun, Marc, Boulanger, Renaud, Lefort, Eveline, Nakamura, Sunao, Motoyoshi, Yudai, Mieulet, Delphine, Campa, Claudine, Legendre, Laurent, and Bertrand, Benoît

Subjects

*COFFEE beans, *LIMONENE, *COFFEE, *TERPENES, *COFFEE flavor & odor, *GENE expression

Abstract

Background: The fruity aromatic bouquet of coffee has attracted recent interest to differentiate high value market produce as specialty coffee. Although the volatile compounds present in green and roasted coffee beans have been extensively described, no study has yet linked varietal molecular differences to the greater abundance of specific substances and support the aroma specificity of specialty coffees. Results: This study compared four Arabica genotypes including one, Geisha Especial, suggested to generate specialty coffee. Formal sensory evaluations of coffee beverages stressed the importance of coffee genotype in aroma perception and that Geisha Especial-made coffee stood out by having fine fruity, and floral, aromas and a more balanced acidity. Comparative SPME–GC–MS analyses of green and roasted bean volatile compounds indicated that those of Geisha Especial differed by having greater amounts of limonene and 3-methylbutanoic acid in agreement with the coffee cup aroma perception. A search for gene ontology differences of ripening beans transcriptomes of the four varieties revealed that they differed by metabolic processes linked to terpene biosynthesis due to the greater gene expression of prenyl-pyrophosphate biosynthetic genes and terpene synthases. Only one terpene synthase (CaTPS10-like) had an expression pattern that paralleled limonene loss during the final stage of berry ripening and limonene content in the studied four varieties beans. Its functional expression in tobacco leaves confirmed its functioning as a limonene synthase. Conclusions: Taken together, these data indicate that coffee variety genotypic specificities may influence ripe berry chemotype and final coffee aroma unicity. For the specialty coffee variety Geisha Especial, greater expression of terpene biosynthetic genes including CaTPS10-like, a limonene synthase, resulted in the greater abundance of limonene in green beans, roasted beans and a unique citrus note of the coffee drink. [ABSTRACT FROM AUTHOR]

Published

2024

2. Chromosome-scale genome assembly of Rhododendron molle provides insights into its evolution and terpenoid biosynthesis

Author

Guo-Lin Zhou, Yong Li, Fei Pei, Ting Gong, Tian-Jiao Chen, Jing-Jing Chen, Jin-Ling Yang, Qi-Han Li, Shi-Shan Yu, and Ping Zhu

Subjects

Rhododendron molle, Grayanoids, Genome, Terpene synthases, Cytochrome P450 monooxygenases, Botany, QK1-989

Abstract

Abstract Background Rhododendron molle (Ericaceae) is a traditional Chinese medicine, which has been used to treat rheumatism and relieve pain since ancient times. The characteristic grayanoids of this plant have been demonstrated to be the chemical basis for the analgesic activity. Moreover, unlike morphine, these diterpenoids are non-addictive. Grayanoids mainly distribute in the leaves, flowers, roots, and fruits of R. molle, with low content. Currently the research on the biosynthesis of grayanoids is hindered, partially due to lack of the genomic information. Results In the present study, a total of 744 Mb sequences were generated and assembled into 13 chromosomes. An ancient whole-genome duplication event (Ad-β) was discovered that occurred around 70 million years ago. Tandem and segmental gene duplications led to specific gene expansions in the terpene synthase and cytochrome P450 (CYP450) gene families. Two diterpene synthases were demonstrated to be responsible for the biosynthesis of 16α-hydroxy-ent-kaurane, the key precursor for grayanoids. Phylogenetic analysis revealed a species-specific bloom of the CYP71AU subfamily, which may involve the candidate CYP450s responsible for the biosynthesis of grayanoids. Additionally, three putative terpene biosynthetic gene clusters were found. Conclusions We reported the first genome assembly of R. molle and investigated the molecular basis underpinning terpenoids biosynthesis. Our work provides a foundation for elucidating the complete biosynthetic pathway of grayanoids and studying the terpenoids diversity in R. molle.

Published

2022

3. Chromosome-scale genome assembly of Rhododendron molle provides insights into its evolution and terpenoid biosynthesis.

Author

Zhou, Guo-Lin, Li, Yong, Pei, Fei, Gong, Ting, Chen, Tian-Jiao, Chen, Jing-Jing, Yang, Jin-Ling, Li, Qi-Han, Yu, Shi-Shan, and Zhu, Ping

Subjects

*RHODODENDRONS, *BIOSYNTHESIS, *CHINESE medicine, *CYTOCHROME P-450, *GENE families, *GENOMES

Abstract

Background: Rhododendron molle (Ericaceae) is a traditional Chinese medicine, which has been used to treat rheumatism and relieve pain since ancient times. The characteristic grayanoids of this plant have been demonstrated to be the chemical basis for the analgesic activity. Moreover, unlike morphine, these diterpenoids are non-addictive. Grayanoids mainly distribute in the leaves, flowers, roots, and fruits of R. molle, with low content. Currently the research on the biosynthesis of grayanoids is hindered, partially due to lack of the genomic information. Results: In the present study, a total of 744 Mb sequences were generated and assembled into 13 chromosomes. An ancient whole-genome duplication event (Ad-β) was discovered that occurred around 70 million years ago. Tandem and segmental gene duplications led to specific gene expansions in the terpene synthase and cytochrome P450 (CYP450) gene families. Two diterpene synthases were demonstrated to be responsible for the biosynthesis of 16α-hydroxy-ent-kaurane, the key precursor for grayanoids. Phylogenetic analysis revealed a species-specific bloom of the CYP71AU subfamily, which may involve the candidate CYP450s responsible for the biosynthesis of grayanoids. Additionally, three putative terpene biosynthetic gene clusters were found. Conclusions: We reported the first genome assembly of R. molle and investigated the molecular basis underpinning terpenoids biosynthesis. Our work provides a foundation for elucidating the complete biosynthetic pathway of grayanoids and studying the terpenoids diversity in R. molle. [ABSTRACT FROM AUTHOR]

Published

2022

4. Next generation sequencing unravels the biosynthetic ability of Spearmint (Mentha spicata) peltate glandular trichomes through comparative transcriptomics.

Author

Jingjing Jin, Panicker, Deepa, Qian Wang, Mi Jung Kim, Jun Liu, Jun-Lin Yin, Limsoon Wong, In-Cheol Jang, Nam-Hai Chua, and Sarojam, Rajani

Subjects

*SPEARMINT, *TRICHOMES, *ESSENTIAL oils, *PHOTOSYNTHESIS, *SESQUITERPENES, *CHEMICAL synthesis, *LIPID transfer protein

Abstract

Background Plant glandular trichomes are chemical factories with specialized metabolic capabilities to produce diverse compounds. Aromatic mint plants produce valuable essential oil in specialised glandular trichomes known as peltate glandular trichomes (PGT). Here, we performed next generation transcriptome sequencing of different tissues of Mentha spicata (spearmint) to identify differentially expressed transcripts specific to PGT. Our results provide a comprehensive overview of PGT's dynamic metabolic activities which will help towards pathway engineering. Results Spearmint RNAs from 3 different tissues: PGT, leaf and leaf stripped of PGTs (leaf-PGT) were sequenced by Illumina paired end sequencing. The sequences were assembled de novo into 40,587 non-redundant unigenes; spanning a total of 101 Mb. Functions could be assigned to 27,025 (67%) unigenes and among these 3,919 unigenes were differentially expressed in PGT relative to leaf - PGT. Lack of photosynthetic transcripts in PGT transcriptome indicated the high levels of purity of isolated PGT, as mint PGT are non-photosynthetic. A significant number of these unigenes remained unannotated or encoded hypothetical proteins. We found 16 terpene synthases (TPS), 18 cytochrome P450s, 5 lipid transfer proteins and several transcription factors that were preferentially expressed in PGT. Among the 16 TPSs, two were characterized biochemically and found to be sesquiterpene synthases. Conclusions The extensive transcriptome data set renders a complete description of genes differentially expressed in spearmint PGT. This will facilitate the metabolic engineering of mint terpene pathway to increase yield and also enable the development of strategies for sustainable production of novel or altered valuable compounds in mint. [ABSTRACT FROM AUTHOR]

Published

2014

5. Next generation sequencing unravels the biosynthetic ability of Spearmint (Mentha spicata) peltate glandular trichomes through comparative transcriptomics

Author

Nam-Hai Chua, Jingjing Jin, Deepa Panicker, Jun Lin Yin, Qian Wang, Limsoon Wong, Rajani Sarojam, Mi Jung Kim, In-Cheol Jang, and Jun Liu

Subjects

Mentha spicata, Sequence analysis, Plant Science, Biology, Spearmint, DNA sequencing, Transcriptome, food, Next generation sequencing, Botany, Terpene synthases, Gene, Paired-end tag, Base Sequence, Terpenes, Gene Expression Profiling, High-Throughput Nucleotide Sequencing, Sequence Analysis, DNA, Trichomes, Carvone, Recombinant Proteins, Trichome, food.food, Plant Leaves, Gene expression profiling, Biochemistry, Organ Specificity, Glandular trichomes, Research Article

Abstract

Background Plant glandular trichomes are chemical factories with specialized metabolic capabilities to produce diverse compounds. Aromatic mint plants produce valuable essential oil in specialised glandular trichomes known as peltate glandular trichomes (PGT). Here, we performed next generation transcriptome sequencing of different tissues of Mentha spicata (spearmint) to identify differentially expressed transcripts specific to PGT. Our results provide a comprehensive overview of PGT’s dynamic metabolic activities which will help towards pathway engineering. Results Spearmint RNAs from 3 different tissues: PGT, leaf and leaf stripped of PGTs (leaf-PGT) were sequenced by Illumina paired end sequencing. The sequences were assembled de novo into 40,587 non-redundant unigenes; spanning a total of 101 Mb. Functions could be assigned to 27,025 (67%) unigenes and among these 3,919 unigenes were differentially expressed in PGT relative to leaf - PGT. Lack of photosynthetic transcripts in PGT transcriptome indicated the high levels of purity of isolated PGT, as mint PGT are non-photosynthetic. A significant number of these unigenes remained unannotated or encoded hypothetical proteins. We found 16 terpene synthases (TPS), 18 cytochrome P450s, 5 lipid transfer proteins and several transcription factors that were preferentially expressed in PGT. Among the 16 TPSs, two were characterized biochemically and found to be sesquiterpene synthases. Conclusions The extensive transcriptome data set renders a complete description of genes differentially expressed in spearmint PGT. This will facilitate the metabolic engineering of mint terpene pathway to increase yield and also enable the development of strategies for sustainable production of novel or altered valuable compounds in mint. Electronic supplementary material The online version of this article (doi:10.1186/s12870-014-0292-5) contains supplementary material, which is available to authorized users.

Published

2014