Potato tuber expression of Arabidopsis <i>WRINKLED1</i> increase triacylglycerol and membrane lipids while affecting central carbohydrate metabolism

Hofvander, Per; Ischebeck, Till; Turesson, Helle; Kushwaha, Sandeep; Feußner, Ivo; Carlsson, Anders S.; Andersson, Mariette

doi:10.1111/pbi.12550

Cited by 73 publications

(77 citation statements)

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“…Starch is a major carbon and energy storage form in leaves and some source tissues such as tubers and therefore expected to compete with lipids for photosynthetic carbon. Previous attempts at engineering elevated levels of storage lipids in a variety of species and tissues did negatively impact transitory or storage starch metabolism (Zale et al ., ; Vanhercke et al ., ; Hofvander et al ., ; Liu et al ., ; Mitchell et al ., ; Vanhercke et al ., ). Quantification of starch levels in transgenic sorghum leaves showed a distinct difference between the two transgenic populations.…”

Section: Discussionmentioning

confidence: 99%

“…Contrary to the results in A. thaliana and tobacco, achievements in other species thus far remain limited to small increases in TAG or total lipids contents. Examples include ryegrass (Beechey-Gradwell, 2016;Winichayakul et al, 2008), corn (Alameldin et al, 2017), potato (Hofvander et al, 2016;Klaus et al, 2004;Liu et al, 2017), Jatropha curcas (Maravi et al, 2016) and rice (Singh et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Up‐regulation of lipid biosynthesis increases the oil content in leaves of Sorghum bicolor

Vanhercke

Belide

Taylor

et al. 2018

Plant Biotechnology Journal

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Synthesis and accumulation of the storage lipid triacylglycerol in vegetative plant tissues has emerged as a promising strategy to meet the world's future need for vegetable oil. Sorghum (Sorghum bicolor) is a particularly attractive target crop given its high biomass, drought resistance and C photosynthesis. While oilseed-like triacylglycerol levels have been engineered in the C model plant tobacco, progress in C monocot crops has been lagging behind. In this study, we report the accumulation of triacylglycerol in sorghum leaf tissues to levels between 3 and 8.4% on a dry weight basis depending on leaf and plant developmental stage. This was achieved by the combined overexpression of genes encoding the Zea mays WRI1 transcription factor, Umbelopsis ramanniana UrDGAT2a acyltransferase and Sesamum indicum Oleosin-L oil body protein. Increased oil content was visible as lipid droplets, primarily in the leaf mesophyll cells. A comparison between a constitutive and mesophyll-specific promoter driving WRI1 expression revealed distinct changes in the overall leaf lipidome as well as transitory starch and soluble sugar levels. Metabolome profiling uncovered changes in the abundance of various amino acids and dicarboxylic acids. The results presented here are a first step forward towards the development of sorghum as a dedicated biomass oil crop and provide a basis for further combinatorial metabolic engineering.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Up‐regulation of lipid biosynthesis increases the oil content in leaves of Sorghum bicolor

Vanhercke

Belide

Taylor

et al. 2018

Plant Biotechnology Journal

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“…For the analysis of free sterols, the extracted lipids of pollen tubes deriving from 5 mg pollen were evaporated under N 2 stream and 20 μl pyridine and 20 μl N ‐methyl‐ N ‐(trimethylsilyl) trifluoroacetamide (MSTFA) was added. The samples were analysed by GC‐MS as described (Hofvander et al ., ), but using an inlet temperature of 230°C and a temperature gradient applied starting with 50°C for 5 min, 50–170°C at 30°C min −1 , 170–325°C at 5°C min −1 and 325°C for 30 min. Helium was used as carrier gas.…”

Section: Methodsmentioning

confidence: 99%

Characterization of the enzymatic activity and physiological function of the lipid droplet‐associated triacylglycerol lipase AtOBL1

Müller¹,

Ischebeck²

2017

New Phytologist

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Similar to seeds, pollen tubes contain lipid droplets that store triacylglycerol (TAG), but the fate of this TAG as well as the enzymes involved in its breakdown are unknown. Therefore, two potential TAG lipases from tobacco and Arabidopsis, NtOBL1 (Oil body lipase 1) and AtOBL1, were investigated, especially with respect to their importance for pollen tube growth. We expressed NtOBL1 and AtOBL1 as fluorescent fusion proteins to study their localization by confocal microscopy. Furthermore, we overexpressed AtOBL1 in Nicotiana benthamiana leaves to characterize it enzymatically. The obl1 mutant was studied in respect to its pollen tube growth in vivo and its seed germination. Both NtOBL1 and AtOBL1 localized to lipid droplets. AtOBL1 was abundant in pollen tubes and seedlings, and acted as a lipase on TAG, diacylglycerol and 1-monoacylglycerol at a pH optimum of 5.5. The obl1 mutant was hampered in pollen tube growth, whereas seedling establishment was not affected under optimal conditions, even though AtOBL1 accounted for a major lipase activity in seeds. TAG could be a direct precursor for the synthesis of membrane lipids in pollen tubes and proteins of the OBL family involved in the flux of acyl groups.

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“…Another study in tobacco achieved TAGs accumulation up to 19% of the dry weight of the total biomass production by over-expressing the genes encoding WRINKLED1, DGAT, and oleosins (Vanhercke et al , 2014; Zale et al , 2016). However, many of these engineering efforts to increase TAG accumulation in immature vegetative tissues have resulted in negative impacts on plant growth as observed in sorghum, potato, tobacco, and Arabidopsis (Slocombe et al , 2009; Feltus and Vandenbrink, 2012; Kelly et al , 2013; Vanhercke et al , 2014, 2019; Hofvander et al , 2016; Liu et al , 2017; Ramšak et al , 2018; Xiaoyu Xu et al , 2019; Xu et al , 2020; Mitchell et al , 2020). One hypothesis is that driving lipid accumulation under the control of tissue- and/or developmental-stage specific promoters, specifically those active during late development (Moyle and Birch, 2013; Mudge et al , 2013), will have less of an impact on photosynthetic efficiencies and plant growth than constitutive overexpression of genes of interest.…”

Section: Introductionmentioning

confidence: 99%

Sorghum bicolorcultivars have divergent and dynamic gene regulatory networks that control the temporal expression of genes in stem tissue

Arachchilage

Mullet

Marshall‐Colón

2020

Preprint

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The genetic engineering of value-added traits such as the accumulation of bioproducts 21 in high biomass C4 grass stems is one promising strategy to make plant-derived biofuels more 22 economical for industrial use. A first step toward achieving this goal is to identify stem-specific 23 promoters that can drive the expression of genes of interest with good temporal and spatial 24 specificity. However, a comprehensive characterization of the spatial-temporal regulatory 25 elements of stem tissue-specific promoters for C4 grasses has not been reported. Therefore, we 26 performed an in-silico analysis on Sorghum bicolor cv BTx623 transcriptomes from multiple 27 tissues over development to identify stem-expressed genes. The analysis identified 10 genes that 28 are "Always-On-Stem-Specific," 59 genes that are "Temporally-Stem-Specific during early 29 development," and 21 genes that are "Temporally-Stem-Specific during late development." 30 Promoter analysis revealed common and/or unique cis-regulatory elements in promoters of genes within each of the three categories. Subsequent gene regulatory network (GRN) analysis revealed 32 that different transcriptional regulatory programs are responsible for the temporal activation of the 33 stem-expressed genes. The analysis of temporal stem GRNs between sweet (cv Della) and grain 34 (cv BTx623) sorghum varieties revealed genetic variation that could influence the regulatory 35 landscape. This study provides new insights about sorghum stem biology, and information for 36 future genetic engineering efforts to fine-tune the spatial-temporal expression of transgenes in C4 37 grass stems. 38 39 40 High biomass grasses, such as sorghum (Sorghum bicolor), miscanthus (Miscanthus x 41 giganteus), switchgrass (Panicum virgatum), and sugarcane (Saccharum sp.), offer an abundant 42 and renewable source of biomass for biofuels production (McLaughlin and Kszos, 2005; Rooney 43 et al.

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Potato tuber expression of Arabidopsis WRINKLED1 increase triacylglycerol and membrane lipids while affecting central carbohydrate metabolism

Cited by 73 publications

References 49 publications

Up‐regulation of lipid biosynthesis increases the oil content in leaves of Sorghum bicolor

Up‐regulation of lipid biosynthesis increases the oil content in leaves of Sorghum bicolor

Characterization of the enzymatic activity and physiological function of the lipid droplet‐associated triacylglycerol lipase AtOBL1

Sorghum bicolorcultivars have divergent and dynamic gene regulatory networks that control the temporal expression of genes in stem tissue

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