Modulating seed β-ketoacyl-acyl carrier protein synthase II level converts the composition of a temperate seed oil to that of a palm-like tropical oil

Pidkowich, Mark S.; Nguyen, Huu Tam; Heilmann, Ingo; Ischebeck, Till; Shanklin, John

doi:10.1073/pnas.0611141104

Cited by 133 publications

(123 citation statements)

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“…Our alignment and phylogenetic analyses showed that the AtKAS2 (At1g74960) gene encodes a functional protein having KAS II activity, being consistent with the complementation experiment of leaky fab1-1 mutant (Carlsson et al, 2002) and with the recently reported fatty-acid composition of knockout fab1-2 mutant (Pidkowich et al, 2007). Thus, AtKAS2 catalyzes the elongation of 16:0-ACP to 18:0-ACP in plastids, and may have many important biological functions in various tissues in various developmental stages.…”

Section: Enzymatic Function and Localization Of Atkas2supporting

confidence: 51%

Expression and developmental function of the 3-ketoacyl-ACP synthase2 gene in Arabidopsis thaliana

et al. 2008

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The 3-ketoacyl-ACP synthase (KAS) II is a fatty-acid-related enzyme which catalyzes the elongation of 16:0-acyl carrier protein (ACP) to 18:0-ACP in plastids. The fatty acid biosynthesis 1-1 (fab1-1) mutant of Arabidopsis thaliana is partially deficient in its activity of Arabidopsis thaliana 3-ketoacyl-ACP synthase 2 (AtKAS2), and its phenotype has been intensively studied in connection with the chilling resistance and fatty acid composition. In this study, we used the T-DNA insertion mutant of AtKAS2 to examine its possible role in plant development. Reverse transcription (RT)-PCR showed that the AtKAS2 gene was expressed in various plant organs, except for roots, and was highly expressed in siliques. The fusion of β-glucuronidase (GUS) to the AtKAS2 promoter demonstrated that the promoter was active in various tissues such as embryos, stomatal guard cells, inflorescences and pollen grains. We were not able to identify atkas2 homozygous mutant adult plants in heterozygous mutant progeny. Phenotypic and genetic analyses showed that disruption of the AtKAS2 by T-DNA insertion caused embryo lethality, and the development of the embryos was arrested at the globular stage. Taken together, our results suggest that AtKAS2 is required for embryo development in Arabidopsis during the transition from the globular to the heart stage.

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Section: Enzymatic Function and Localization Of Atkas2supporting

confidence: 51%

Expression and developmental function of the 3-ketoacyl-ACP synthase2 gene in Arabidopsis thaliana

et al. 2008

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“…The plants were transformed according to Clough and Bent's method (Clough and Bent, 1998) using Agrobacterium tumefaciens strain GV3101. We identified individual T1 seeds carrying the transgenes by the fluorescence emitted (Stuitje et al, 2003) upon illumination with green light from an X5 LED flashlight (Inova) in conjunction with a 25A red camera filter (Pidkowich et al, 2007). A WILD M3Z dissection microscope equipped with an Olympus U-LH100HG illumination system was used to discriminate between seeds carrying Zs-Green and Ds-Red markers with the use of filters fluorescein isothiocyanate 535 and fluorescein isothiocyanate 515, respectively.…”

Section: Arabidopsis Growth and Transformationmentioning

confidence: 99%

“…Two such lines were recently reported in which fab1 was suppressed, one by hairpin RNA interference (RNAi; Pidkowich et al, 2007) and the other by a novel method of suppression termed hairpin-antisense (HPAS) RNAi (Nguyen and Shanklin, 2009). These lines contain strongly elevated seed 16:0 accumulation levels at 42% and 46%, respectively (Fig.…”

mentioning

confidence: 99%

Metabolic Engineering of Seeds Can Achieve Levels of ω-7 Fatty Acids Comparable with the Highest Levels Found in Natural Plant Sources

Nguyen

Mishra²,

Whittle³

et al. 2010

Plant Physiology

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Plant oils containing v-7 fatty acids (FAs; palmitoleic 16:1D 9 and cis-vaccenic 18:1D 11 ) have potential as sustainable feedstocks for producing industrially important octene via metathesis chemistry. Engineering plants to produce seeds that accumulate high levels of any unusual FA has been an elusive goal. We achieved high levels of v-7 FA accumulation by systematic metabolic engineering of Arabidopsis (Arabidopsis thaliana). A plastidial 16:0-ACP desaturase has been engineered to convert 16:0 to 16:1D 9 with specificity .100-fold than that of naturally occurring paralogs, such as that from cat's claw vine (Doxantha unguis-cati). Expressing this engineered enzyme (Com25) in seeds increased v-7 FA accumulation from ,2% to 14%. Reducing competition for 16:0-ACP by down-regulating the b-ketoacyl-ACP synthase II 16:0 elongase further increased accumulation of v-7 FA to 56%. The level of 16:0 exiting the plastid without desaturation also increased to 21%. Coexpression of a pair of fungal 16:0 desaturases in the cytosol reduced the 16:0 level to 11% and increased v-7 FA to as much as 71%, equivalent to levels found in Doxantha seeds.There is increasing interest in the use of plant oils as renewable sources of industrial chemical feedstocks Carlsson, 2009). Recent developments in olefin metathesis have demonstrated that long-chain monoene FA from vegetable oils can be efficiently split into the corresponding short-chain a-olefin and v-alkenoic acids (Rybak et al., 2008;Meier, 2009). Thus, ethenolytic metathesis of v-7 fatty acids (FAs), such as palmitoleic or cis-vaccenic acids, yields 1-octene and 9-decenoate. 1-Octene is a high-demand feedstock with a global consumption of over half a million tons per year that is primarily used as a comonomer in the expanding production of linear low density polyethylene. It is mainly synthesized from petroleumderived ethylene via oligomerization to yield a complex mixture of a-olefins or from coal-derived syngas (Anonymous, 2007).A plant oil containing high (.70%) content of v-7 FA would represent a new and sustainable feedstock for 1-octene production. Several natural plant oil sources of v-7 FA have been reported, e.g. milkweed (Asclepias syriaca) accumulates approximately 25% v-7 FA (comprising approximately 10% 16:1D 9 and approximately 15% 18:1D 11 ) and cat's claw vine (Doxantha unguis-cati) accumulates approximately 72% v-7 FA (comprising approximately 55% 16:1D 9 and approximately 17% 18:1D 11 ), but the low yields and poor agronomic properties of these plants preclude their commercial use for v-7 FA production. Isolation of the D 9 -16:0-ACP desaturases genes responsible for the production of v-7 FA from milkweed and Doxantha (Cahoon et al., 1997 presented an opportunity for their heterologous expression and v-7 FA production in transgenic crops. However, heterologous expression of the milkweed desaturase in Arabidopsis (Arabidopsis thaliana) failed to produce detectable v-7 FA, and when the Doxantha desaturase was expressed in Brassica napus, it resulted in the accumul...

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“…Hasil studi pada tanaman model A. thaliana menunjukkan bahwa penurunan tingkat aktivitas enzim KASII sudah mencukupi untuk mengkonversi minyak pada biji Arabidopsis menyerupai karakteristik minyak kelapa sawit (Pidkowich et al, 2007). Penggunaan promoter yang diekspresikan spesifik pada mesocarp kelapa sawit (mesocarp-specific promoter) dan aplikasi metode antisense RNA dari gen KASII dan gen palmitoyl-ACP thio esterase diharapkan menghasilkan tanaman transgenik dengan komposisi minyak yang kaya akan asam lemak tak jenuh seperti asam oleat.…”

Section: Kemajuan Dan Potensi Aplikasiunclassified

PEMANFAATAN TEKNOLOGI GENOMIKA DAN TRANSFORMASI GENETIK UNTUK MENINGKATKAN PRODUKTIVITAS KELAPA SAWIT / The Use of Genomic and Genetic Transformation Technologies for Oil Palm Productivity Improvement

Tasma¹

2017

PSP

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ABSTRAKSalah satu kendala budidaya kelapa sawit adalah rendahnya produktivitas dengan rataan nasional 4 ton minyak/ha/tahun jauh dari potensinya yang dapat mencapai 18,5 ton minyak/ha/tahun. Pemuliaan kelapa sawit secara konvensional sangat lambat dan perlu waktu panjang. Diperlukan 10-12 tahun hanya untuk menyelesaikan satu siklus pemuliaan. Aplikasi teknologi genomika melalui pemuliaan berbantuan marka dan rekayasa genetika mempercepat siklus pemuliaan, mengurangi luas lahan untuk uji daya hasil, dan mempercepat pelepasan varietas unggul kelapa sawit. Tujuan dari tulisan ini untuk mengulas pemanfaatan teknologi genomika dan transformasi genetik untuk perbaikan produktivitas kelapa sawit dan potensi aplikasinya untuk perbaikan produktivitas kelapa sawit di Indonesia. Teknologi genomika telah menghasilkan peta genom acuan dua spesies kelapa sawit (Elaeis guineensis dan Elaeis oleifera) yang menghasilkan gen Shell (Sh) yang mengendalikan heterosis hasil minyak, ditemukan mekanisme terbentuknya buah mantel, dan sebagai fondasi untuk penemuan gen-gen unggul dan pengembangan marka molekuler kapasitas tinggi yang mengakselerasi program pemuliaan kelapa sawit. Pemanfaatan marka gen Sh dan kit pendeteksi bibit penghasil buah mantel mempercepat siklus pemuliaan kelapa sawit dan sarana seleksi bibit tenera unggul untuk menjamin peningkatan produktivitas kelapa sawit. Perbanyakan individu tanaman unggul terpilih dengan teknik kultur in vitro menjamin penggunaan bibit yang seragam di lapang.Teknologi rekayasa genetika potensial digunakan untuk perbaikan bahan tanaman kelapa sawit dengan kualitas dan gizi minyak tinggi serta produk kelapa sawit yang dapat digunakan sebagai bioplastik. Resekuensing tiga genotipe kelapa sawit Indonesia menghasilkan jutaan variasi genom sebagai sumberdaya pemuliaan bernilai tinggi untuk percepatan program pemuliaan kelapa sawit nasional. Teknologi genomika dan rekayasa genetika sangat potensial diaplikasikan di Indonesia mendukung program perbaikan produktivitas dan mutu minyak kelapa sawit nasional.

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Modulating seed β-ketoacyl-acyl carrier protein synthase II level converts the composition of a temperate seed oil to that of a palm-like tropical oil

Cited by 133 publications

References 28 publications

Expression and developmental function of the 3-ketoacyl-ACP synthase2 gene in Arabidopsis thaliana

Expression and developmental function of the 3-ketoacyl-ACP synthase2 gene in Arabidopsis thaliana

Metabolic Engineering of Seeds Can Achieve Levels of ω-7 Fatty Acids Comparable with the Highest Levels Found in Natural Plant Sources

PEMANFAATAN TEKNOLOGI GENOMIKA DAN TRANSFORMASI GENETIK UNTUK MENINGKATKAN PRODUKTIVITAS KELAPA SAWIT / The Use of Genomic and Genetic Transformation Technologies for Oil Palm Productivity Improvement

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