Your search keyword '"phytyl ester synthase"' showing total 3 results

1. The Carotenoid Esterification Gene BrPYP Controls Pale-Yellow Petal Color in Flowering Chinese Cabbage (Brassica rapa L. subsp. parachinensis).

Author

Li, Peirong, Lv, Sirui, Zhang, Deshuang, Su, Tongbing, Xin, Xiaoyun, Wang, Weihong, Zhao, Xiuyun, Yu, Yangjun, Zhang, Yaowei, Yu, Shuancang, and Zhang, Fenglan

Subjects

CHINESE cabbage, CAROTENOIDS, FLOWER petals, ESTERIFICATION, BRASSICA, RECESSIVE genes

Abstract

Carotenoid esterification plays indispensable roles in preventing degradation and maintaining the stability of carotenoids. Although the carotenoid biosynthetic pathway has been well characterized, the molecular mechanisms underlying carotenoid esterification, especially in floral organs, remain poorly understood. In this study, we identified a natural mutant flowering Chinese cabbage (Caixin, Brassica rapa L. subsp. chinensis var. parachinensis) with visually distinguishable pale-yellow petals controlled by a single recessive gene. Transmission electron microscopy (TEM) demonstrated that the chromoplasts in the yellow petals were surrounded by more fully developed plastoglobules compared to the pale-yellow mutant. Carotenoid analyses further revealed that, compared to the pale-yellow petals, the yellow petals contained high levels of esterified carotenoids, including lutein caprate, violaxanthin dilaurate, violaxanthin-myristate-laurate, 5,6epoxy-luttein dilaurate, lutein dilaurate, and lutein laurate. Based on bulked segregation analysis and fine mapping, we subsequently identified the critical role of a phytyl ester synthase 2 protein (PALE YELLOW PETAL , BrPYP) in regulating carotenoid pigmentation in flowering Chinese cabbage petals. Compared to the yellow wild-type, a 1,148 bp deletion was identified in the promoter region of BrPYP in the pale-yellow mutant, resulting in down-regulated expression. Transgenic Arabidopsis plants harboring beta-glucuronidase (GUS) driven by yellow (BrPYP Y ::GUS) and pale-yellow type (BrPYP PY ::GUS) promoters were subsequently constructed, revealing stronger expression of BrPYP Y ::GUS both in the leaves and petals. Furthermore, virus-induced gene silencing of BrPYP significantly altered petal color from yellow to pale yellow. These findings demonstrate the molecular mechanism of carotenoid esterification, suggesting a role of phytyl ester synthase in carotenoid biosynthesis of flowering Chinese cabbage. [ABSTRACT FROM AUTHOR]

Published

2022

2. The Carotenoid Esterification Gene BrPYP Controls Pale-Yellow Petal Color in Flowering Chinese Cabbage (Brassica rapa L. subsp. parachinensis)

Author

Peirong Li, Sirui Lv, Deshuang Zhang, Tongbing Su, Xiaoyun Xin, Weihong Wang, Xiuyun Zhao, Yangjun Yu, Yaowei Zhang, Shuancang Yu, and Fenglan Zhang

Subjects

carotenoid esterification, pale yellow petals, phytyl ester synthase, plastoglobules, flowering Chinese cabbage, Plant culture, SB1-1110

Abstract

Carotenoid esterification plays indispensable roles in preventing degradation and maintaining the stability of carotenoids. Although the carotenoid biosynthetic pathway has been well characterized, the molecular mechanisms underlying carotenoid esterification, especially in floral organs, remain poorly understood. In this study, we identified a natural mutant flowering Chinese cabbage (Caixin, Brassica rapa L. subsp. chinensis var. parachinensis) with visually distinguishable pale-yellow petals controlled by a single recessive gene. Transmission electron microscopy (TEM) demonstrated that the chromoplasts in the yellow petals were surrounded by more fully developed plastoglobules compared to the pale-yellow mutant. Carotenoid analyses further revealed that, compared to the pale-yellow petals, the yellow petals contained high levels of esterified carotenoids, including lutein caprate, violaxanthin dilaurate, violaxanthin-myristate-laurate, 5,6epoxy-luttein dilaurate, lutein dilaurate, and lutein laurate. Based on bulked segregation analysis and fine mapping, we subsequently identified the critical role of a phytyl ester synthase 2 protein (PALE YELLOW PETAL, BrPYP) in regulating carotenoid pigmentation in flowering Chinese cabbage petals. Compared to the yellow wild-type, a 1,148 bp deletion was identified in the promoter region of BrPYP in the pale-yellow mutant, resulting in down-regulated expression. Transgenic Arabidopsis plants harboring beta-glucuronidase (GUS) driven by yellow (BrPYPY::GUS) and pale-yellow type (BrPYPPY::GUS) promoters were subsequently constructed, revealing stronger expression of BrPYPY::GUS both in the leaves and petals. Furthermore, virus-induced gene silencing of BrPYP significantly altered petal color from yellow to pale yellow. These findings demonstrate the molecular mechanism of carotenoid esterification, suggesting a role of phytyl ester synthase in carotenoid biosynthesis of flowering Chinese cabbage.

Published

2022

3. Genetically modified tobacco (Nicotiana tabacum) plants for an increased production of wax esters

Author

Nilsson, Linn and Nilsson, Linn

Abstract

Wax esters (WE) are naturally occurring lipids consisting of a fatty acid bound to a fatty alcohol with an ester bond. As an alternative to petrochemicals, plant-derived WE:s are of considerable commercial interest as lubricants, but have in recent years also received great attention for their potential as a starting material for bio-fuel production. It was recently shown that WE:s can be overproduced in stably transformed tobacco plants carrying a gene fusion between two genes encoding a fatty acid reductase (FAR) and wax ester synthase (PES), thus forming a single WE-synthesizing enzyme (Aslan 2015). Chloroplast- directed overexpression of the fusion enzyme led to an 8-fold induction of WE levels (0.15 % by dry weight) in transgenic plants (Aslan et al. 2015). However, this work also revealed negative growth effects, likely from high levels of the intermediate metabolite fatty alcohol, possibly inhibiting higher levels of WE production. The present study was undertaken to investigate the possibility of increasing the WE levels in transgenic plants even further. Through different genetic approaches, a small number of transgenic tobacco lines overexpressing both FAR and PES were demonstrated to have a higher survival rate and a new phenotype compared to previous transformants. One of these lines, resulting from a cross of separately transformed FAR- and PES lines (FARxPES) was shown to have an increased WE level compared to the wild-type. These results will now be a basis for further investigations on WE production in transgenic plants.

Published

2022