The impact of cold stress on genes expression pattern of mono- and sesquiterpene biosynthesis and their contents in Ocimum basilicum L

Basil (Ocimum basilicum L.) contains valuable monoterpene and sesquiterpene compounds used for medical purposes. Environmental stresses are suggested to change the essential oil composition in medicinal plants. In the current investigation, an experiment was arranged in greenhouse to study the effect of cold stress on genes expression patterns of linalool synthase (LIS), β-myrcene synthase (MYS), γ-cadinene synthase (CDS), germacrene D synthase (GDS) and geraniol synthase (GES) which is involved in monoterpenes and sesquiterpenes biosynthesis in O. basilicum. The monoterpenes and sesquiterpenes composition and content were also investigated. Plants were exposed to temperatures 22 (control), 4 and 10 °C at 6 to 8 leaf stage for 12, 24 and 48 h. The genes expression levels were determined by real time PCR in plant leaves. Essential oil was extracted at flowering stage by distillation using Clevenger apparatus and its compounds were identified using gas chromatography/mass spectrometry (GC-MS). The results revealed that the LIS expression increasingly occurred to 4.86 fold at 10 °C after 12 h while that of GES reached to 5.7 fold at 10 °C after 48 h. Temperature 4 °C for 12 h increased the expression levels of MYS and GDS genes to 41.5 and 14.2 fold, respectively, while the expression level of CDS increased to 25.5 fold at 4 °C for 48 h. Significant differences (P ≤ 0.01) were observed among treatments with respect to all compounds except α-pinene and camphene. The maximum proportion of geraniol and γ-cadinene were observed at 4 °C for 24 h, while the maximum proportion of germacrene D and α-bergamotene obtained at 10 °C for 12 h. The highest proportion of 1, 8-cineole was achieved at 4 °C for 48 h. Positive associations between germacrene D content and GDS expression (r = 0.8, P ≤ 0.05) and γ-cadinene and CDS expression (r = 0.78, P ≤ 0.05) proposed that the content of terpenoid compounds in basil can be enhanced through increasing the expression levels of genes involved in their biosynthesis.

Enhancing linalool production by engineering oleaginous yeast Yarrowia lipolytica

In this study, stepwise increases in linalool production were obtained by combining metabolic engineering and process optimization of an unconventional oleaginous yeast Yarrowia lipolytica. The linalool synthetic pathway was successfully constructed by heterologously expressing a codon-optimized linalool synthase gene from Actinidia arguta in Y. lipolytica. To enhance linalool productivity, key genes involved in the mevalonate pathway were overexpressed in different combinations. Moreover, the overexpression of mutant ERG20^F88W-N119W gene resulted in further linalool production. A maximum linalool titre of 6.96±0.29mg/L was achieved in shake flasks, which was the highest level ever reported in yeasts.

Metabolic engineering of Saccharomyces cerevisiae for linalool production

OBJECTIVES

To engineer the yeast Saccharomyces cerevisiae for the heterologous production of linalool.

RESULTS

Expression of linalool synthase gene from Lavandula angustifolia enabled heterologous production of linalool in S. cerevisiae. Downregulation of ERG9 gene, that encodes squalene synthase, by replacing its native promoter with the repressible MET3 promoter in the presence of methionine resulted in accumulation of 78 µg linalool l(-1) in the culture medium. This was more than twice that produced by the control strain. The highest linalool titer was obtained by combined repression of ERG9 and overexpression of tHMG1. The yeast strain harboring both modifications produced 95 μg linalool l(-1).

CONCLUSIONS

Although overexpression of tHMG1 and downregulation of ERG9 enhanced linalool titers threefold in the engineered yeast strain, alleviating linalool toxicity is necessary for further improvement of linalool biosynthesis in yeast.

A domain swapping approach to elucidate differential regiospecific hydroxylation by geraniol and linalool synthases from perilla

Geraniol and linalool are acyclic monoterpenes found in plant essential oils that have attracted much attention for their commercial use and in pharmaceutical studies. They are synthesized from geranyl diphosphate (GDP) by geraniol and linalool synthases, respectively. Both synthases are very similar at the amino acid level and share the same substrate; however, the position of the GDP to which they introduce hydroxyl groups is different. In this study, the mechanisms underlying the regiospecific hydroxylation of geraniol and linalool synthases were investigated using a domain swapping approach and site-directed mutagenesis in perilla. Sequences of the synthases were divided into ten domains (domains I to IV-4), and each corresponding domain was exchanged between both enzymes. It was shown that different regions were important for the formation of geraniol and linalool, namely, domains IV-1 and -4 for geraniol, and domains III-b, III-d, and IV-4 for linalool. These results suggested that the conformation of carbocation intermediates and their electron localization were seemingly to be different between geraniol and linalool synthases. Further, five amino acids in domain IV-4 were apparently indispensable for the formation of geraniol and linalool. According to three-dimensional structural models of the synthases, these five residues seemed to be responsible for the different spatial arrangement of the amino acid at H524 in the case of geraniol synthase, while N526 is the corresponding residue in linalool synthase. These results suggested that the side-chains of these five amino acids, in combination with several relevant domains, localized the positive charge in the carbocation intermediate to determine the position of the introduced hydroxyl group.

Enhanced levels of S-linalool by metabolic engineering of the terpenoid pathway in spike lavender leaves

Transgenic Lavandula latifolia plants overexpressing the linalool synthase (LIS) gene from Clarkia breweri, encoding the LIS enzyme that catalyzes the synthesis of linalool were generated. Most of these plants increased significantly their linalool content as compared to controls, especially in the youngest leaves, where a linalool increase up to a 1000% was observed. The phenotype of increased linalool content observed in young leaves was maintained in those T1 progenies that inherit the LIS transgene, although this phenotype was less evident in the flower essential oil. Cross-pollination of transgenic spike lavender plants allowed the generation of double transgenic plants containing the DXS (1-deoxy-d-xylulose-5-P synthase), coding for the first enzyme of the methyl-d-erythritol-4-phosphate pathway, and LIS genes. Both essential oil yield and linalool content in double DXS-LIS transgenic plants were lower than that of their parentals, which could be due to co-suppression effects linked to the structures of the constructs used.

Studies on the expression of linalool synthase using a promoter-β-glucuronidase fusion in transgenic Artemisia annua

Artemisinin, an antimalarial endoperoxide sesquiterpene, is synthesized in glandular trichomes of Artemisia annua L. A number of other enzymes of terpene metabolism utilize intermediates of artemisinin biosynthesis, such as isopentenyl and farnesyl diphosphate, and may thereby influence the yield of artemisinin. In order to study the expression of such enzymes, we have cloned the promoter regions of some enzymes and fused them to β-glucuronidase (GUS). In this study, we have investigated the expression of the monoterpene synthase linalool synthase (LIS) using transgenic A. annua carrying the GUS gene under the control of the LIS promoter. The 652bp promoter region was cloned by the genome walker method. A number of putative cis-acting elements were predicted indicating that the LIS is driven by a complex regulation mechanism. Transgenic plants carrying the promoter-GUS fusion showed specific expression of GUS in T-shaped trichomes (TSTs) but not in glandular secretory trichomes, which is the site for artemisinin biosynthesis. GUS expression was observed at late stage of flower development in styles of florets and in TSTs and guard cells of basal bracts. GUS expression after wounding showed that LIS is involved in plant responsiveness to wounding. Furthermore, the LIS promoter responded to methyl jasmonate (MeJA). These results indicate that the promoter carries a number of cis-acting regulatory elements involved in the tissue-specific expression of LIS and in the response of the plant to wounding and MeJA treatment. Southern blot analysis indicated that the GUS gene was integrated in the A. annua genome as single or multi copies in different transgenic lines. Promoter activity analysis by qPCR showed that both the wild-type and the recombinant promoter are active in the aerial parts of the plant while only the recombinant promoter was active in roots. Due to the expression in TSTs but not in glandular trichomes, it may be concluded that LIS expression will most likely have little or no effect on artemisinin production.