Abstract
Carotenoids have been shown to be essential for human nutrition. Consumption of carotenoid-rich fruits and vegetables can reduce the risk of many diseases. The ketocarotenoid astaxanthin has become a commercially valuable compound due to its powerful antioxidant properties compared to other carotenoids. It is naturally produced in certain algae, bacteria, and the flowers of some species of the genus Adonis, although it is produced in such small quantities in these organisms that it is costly to extract. Chemical synthesis of this compound has also shown limited success with a high proportion of esterified forms of astaxanthin being produced, which decreases antioxidant properties by the conversion of hydroxyl groups to esters. Previously, transgenic astaxanthin-producing plants have been created using a β-carotene ketolase enzyme of either bacterial or algal origin. However, a novel astaxanthin pathway exists in the flowering plants of the genus Adonis which has not been utilized in the same manner. The pathway involves two unique enzymes, β-ring-4-dehydrogenase and 4-hydroxy-β-ring-4-dehydrogenase, which add the necessary hydroxyl and ketone groups to the rings of β-carotene. In the present study, Nicotiana benthamiana plants were transformed with chimeric constructs coding for these two enzymes. The regenerated, transgenic plants accumulate astaxanthin and their growth (height and weight) was unaffected, when compared to non-transformed N. benthamiana and to plants transformed with the bacterial β-carotene ketolase. The accumulation of astaxanthin also improved seedling survivability under harsh UV light, mitigated reactive oxygen accumulation, and provided a phenotype (color) that allowed the efficient identification and recovery of transgenic plants with and without selection.
Highlights
Carotenoids are an important class of dietary compounds due to their nutraceutical properties
In this study we demonstrated that the genes coding for two enzymes, HBFD1 and CBFD2, from the genus Adonis serve as an alternative method for producing astaxanthin in transgenic N. benthamiana
We found that plants transformed with these two genes accumulated astaxanthin at levels similar to previous studies (Table 2; Supplementary Table S4) (Zhong et al, 2011; Huang et al, 2013), the plant’s phenotype was minimally affected, and in most cases the plants with the A. aestivalis biosynthetic pathway grew more similar to the non-transformed plants than the plants with the Brevundimonas sp
Summary
Carotenoids are an important class of dietary compounds due to their nutraceutical properties. Astaxanthin, is a high-valued compound due to its increased antioxidant potential relative to other carotenoids and the limited number of organisms that produce it naturally (O’Connor and O’Brien, 1998). It is used industrially as a food colorant, dietary supplement, and in aquaculture as a feed. Astaxanthin is a β-carotene molecule with hydroxyl groups added at the 3,3’ and ketone groups at the 4,4’ of the β-rings (Higuera-Ciapara et al, 2006) (Figure 1A) Due to these additional oxygen-containing groups, astaxanthin has higher antioxidant potential compared to other carotenoids more commonly synthesized in plants
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
