TY - JOUR
T1 - Installing the neurospora carotenoid pathway in plants enables cytosolic formation of provitamin A and its sequestration in lipid droplets
AU - Zheng, Xiongjie
AU - Zhang, Yasha
AU - Balakrishna, Aparna
AU - Liew, Kit Xi
AU - Kuijer, Hendrik N.J.
AU - Xiao, Ting Ting
AU - Blilou, Ikram
AU - Al-Babili, Salim
N1 - Funding Information:
This work was supported by baseline funding and Competitive Research Grants ( CRG 2017 ; CRG 2020 ) given to Salim Al-Babili from King Abdullah University of Science and Technology (KAUST).
Publisher Copyright:
© 2023 The Author
PY - 2023/6/5
Y1 - 2023/6/5
N2 - Vitamin A deficiency remains a severe global health issue, which creates a need to biofortify crops with provitamin A carotenoids (PACs). Expanding plant cell capacity for synthesis and storing of PACs outside the plastids is a promising biofortification strategy that has been little explored. Here, we engineered PAC formation and sequestration in the cytosol of Nicotiana benthamiana leaves, Arabidopsis seeds, and citrus callus cells, using a fungal (Neurospora crassa) carotenoid pathway that consists of only three enzymes converting C5 isopentenyl building blocks formed from mevalonic acid into PACs, including β-carotene. This strategy led to the accumulation of significant amounts of phytoene and γ- and β-carotene, in addition to fungal, health-promoting carotenes with 13 conjugated double bonds, such as the PAC torulene, in the cytosol. Increasing the isopentenyl diphosphate pool by adding a truncated Arabidopsis hydroxymethylglutaryl-coenzyme A reductase substantially increased cytosolic carotene production. Engineered carotenes accumulate in cytosolic lipid droplets (CLDs), which represent a novel sequestering sink for storing these pigments in plant cytosol. Importantly, β-carotene accumulated in the cytosol of citrus callus cells was more light stable compared to compared with plastidial β-carotene. Moreover, engineering cytosolic carotene formation increased the number of large-sized CLDs and the levels of β-apocarotenoids, including retinal, the aldehyde corresponding to vitamin A. Collectively, our study opens up the possibility of exploiting the high-flux mevalonic acid pathway for PAC biosynthesis and enhancing carotenoid sink capacity in green and non-green plant tissues, especially in lipid-storing seeds, and thus paves the way for further optimization of carotenoid biofortification in crops.
AB - Vitamin A deficiency remains a severe global health issue, which creates a need to biofortify crops with provitamin A carotenoids (PACs). Expanding plant cell capacity for synthesis and storing of PACs outside the plastids is a promising biofortification strategy that has been little explored. Here, we engineered PAC formation and sequestration in the cytosol of Nicotiana benthamiana leaves, Arabidopsis seeds, and citrus callus cells, using a fungal (Neurospora crassa) carotenoid pathway that consists of only three enzymes converting C5 isopentenyl building blocks formed from mevalonic acid into PACs, including β-carotene. This strategy led to the accumulation of significant amounts of phytoene and γ- and β-carotene, in addition to fungal, health-promoting carotenes with 13 conjugated double bonds, such as the PAC torulene, in the cytosol. Increasing the isopentenyl diphosphate pool by adding a truncated Arabidopsis hydroxymethylglutaryl-coenzyme A reductase substantially increased cytosolic carotene production. Engineered carotenes accumulate in cytosolic lipid droplets (CLDs), which represent a novel sequestering sink for storing these pigments in plant cytosol. Importantly, β-carotene accumulated in the cytosol of citrus callus cells was more light stable compared to compared with plastidial β-carotene. Moreover, engineering cytosolic carotene formation increased the number of large-sized CLDs and the levels of β-apocarotenoids, including retinal, the aldehyde corresponding to vitamin A. Collectively, our study opens up the possibility of exploiting the high-flux mevalonic acid pathway for PAC biosynthesis and enhancing carotenoid sink capacity in green and non-green plant tissues, especially in lipid-storing seeds, and thus paves the way for further optimization of carotenoid biofortification in crops.
KW - carotenoid biosynthesis
KW - carotenoid sequestration
KW - carotenoid stability
KW - cytosolic lipid droplets
KW - metabolic engineering
KW - Neurospora crassa
KW - provitamin A
KW - synthetic metabolism
UR - http://www.scopus.com/inward/record.url?scp=85160510943&partnerID=8YFLogxK
U2 - 10.1016/j.molp.2023.05.003
DO - 10.1016/j.molp.2023.05.003
M3 - Article
C2 - 37198885
AN - SCOPUS:85160510943
SN - 1674-2052
VL - 16
SP - 1066
EP - 1081
JO - Molecular plant
JF - Molecular plant
IS - 6
ER -