Nicholas Neumann, Tao Fei, Tong Wang, Timothy P. Durrett
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Even small amounts of regular TAG when blended with acetyl-TAG had a disproportionate effect on the viscosity of mixture. This effect of regular TAG in increasing kinematic viscosity was more pronounced at lower temperatures. Under slow cooling conditions, the two different TAGs and their blends possessed two main crystallization events with different degree of separation of the thermal transition, and the lower crystallization temperature decreased with increasing amounts of acetyl-TAG in the blend. At higher cooling rates, one broad and tailed crystallization peak was observed. Heating thermograms indicate similar polymorphic behavior of the blends and a general peak shift to lower transition range with increasing acetyl-TAG compared to the two pure lipids. This information about the viscosity and thermal properties of blends of TAG and acetyl-TAG will provide useful targets for engineering higher levels of acetyl-TAG in transgenic seeds.</p>","PeriodicalId":17182,"journal":{"name":"Journal of the American Oil Chemists Society","volume":"101 2","pages":"197-204"},"PeriodicalIF":1.9000,"publicationDate":"2023-09-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/aocs.12746","citationCount":"0","resultStr":"{\"title\":\"Defining the physical properties of blends of acetyl-triacylglycerols derived from transgenic oil seeds\",\"authors\":\"Nicholas Neumann, Tao Fei, Tong Wang, Timothy P. Durrett\",\"doi\":\"10.1002/aocs.12746\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Acetyl-TAG are unusually structured triacylglycerols (TAG) that possess an acetate group at their <i>sn</i>-3 position. 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Under slow cooling conditions, the two different TAGs and their blends possessed two main crystallization events with different degree of separation of the thermal transition, and the lower crystallization temperature decreased with increasing amounts of acetyl-TAG in the blend. At higher cooling rates, one broad and tailed crystallization peak was observed. Heating thermograms indicate similar polymorphic behavior of the blends and a general peak shift to lower transition range with increasing acetyl-TAG compared to the two pure lipids. 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引用次数: 0
摘要
乙酰-TAG 是一种结构特殊的三酰甘油 (TAG),在其 sn-3 位置具有一个乙酸基团。与普通 TAG 相比,乙酰基-TAG 具有不同的物理性质,包括较低的粘度和更好的低温性能,这使得乙酰基-TAG 有助于不同的应用,包括用作柴油替代品。通过表达从不同欧鼠李品种中分离出来的二乙酰甘油乙酰转移酶(DAcT),可以在转基因植物种子中合成这些不同寻常的 TAG 分子。本研究考察了乙酰-TAG 和普通 TAG 混合物的运动粘度以及结晶和熔化行为,以确定在转基因植物中合成乙酰-TAG 的目标。即使是少量的普通 TAG 与乙酰-TAG 混合,也会对混合物的粘度产生不成比例的影响。普通 TAG 增加运动粘度的效果在较低温度下更为明显。在缓慢冷却条件下,两种不同的 TAG 及其混合物有两种主要的结晶现象,热转变的分离程度不同,且较低的结晶温度随混合物中乙酰-TAG 含量的增加而降低。在较高的冷却速率下,可观察到一个宽尾结晶峰。加热热图显示,与两种纯脂相比,混合物具有类似的多晶型行为,随着乙酰基-TAG 含量的增加,结晶峰普遍向较低的转变范围移动。有关 TAG 和乙酰基-TAG 混合物的粘度和热特性的这些信息将为在转基因种子中设计更高水平的乙酰基-TAG 提供有用的目标。
Defining the physical properties of blends of acetyl-triacylglycerols derived from transgenic oil seeds
Acetyl-TAG are unusually structured triacylglycerols (TAG) that possess an acetate group at their sn-3 position. Acetyl-TAG have different physical properties compared to regular TAG, including lower viscosity and improved cold temperature properties, making acetyl-TAG useful for different applications, including as a diesel replacement. These unusual TAG molecules can be synthesized in the seeds of transgenic plants through the expression of diacylglycerol acetyltransferase (DAcT) enzymes isolated from different Euonymus species. In this study, the kinematic viscosity as well as the crystallization and melting behavior of blends of acetyl-TAG and regular TAG were examined to define goals for acetyl-TAG synthesis in transgenic plants. Even small amounts of regular TAG when blended with acetyl-TAG had a disproportionate effect on the viscosity of mixture. This effect of regular TAG in increasing kinematic viscosity was more pronounced at lower temperatures. Under slow cooling conditions, the two different TAGs and their blends possessed two main crystallization events with different degree of separation of the thermal transition, and the lower crystallization temperature decreased with increasing amounts of acetyl-TAG in the blend. At higher cooling rates, one broad and tailed crystallization peak was observed. Heating thermograms indicate similar polymorphic behavior of the blends and a general peak shift to lower transition range with increasing acetyl-TAG compared to the two pure lipids. This information about the viscosity and thermal properties of blends of TAG and acetyl-TAG will provide useful targets for engineering higher levels of acetyl-TAG in transgenic seeds.
期刊介绍:
The Journal of the American Oil Chemists’ Society (JAOCS) is an international peer-reviewed journal that publishes significant original scientific research and technological advances on fats, oils, oilseed proteins, and related materials through original research articles, invited reviews, short communications, and letters to the editor. We seek to publish reports that will significantly advance scientific understanding through hypothesis driven research, innovations, and important new information pertaining to analysis, properties, processing, products, and applications of these food and industrial resources. Breakthroughs in food science and technology, biotechnology (including genomics, biomechanisms, biocatalysis and bioprocessing), and industrial products and applications are particularly appropriate.
JAOCS also considers reports on the lipid composition of new, unique, and traditional sources of lipids that definitively address a research hypothesis and advances scientific understanding. However, the genus and species of the source must be verified by appropriate means of classification. In addition, the GPS location of the harvested materials and seed or vegetative samples should be deposited in an accredited germplasm repository. Compositional data suitable for Original Research Articles must embody replicated estimate of tissue constituents, such as oil, protein, carbohydrate, fatty acid, phospholipid, tocopherol, sterol, and carotenoid compositions. Other components unique to the specific plant or animal source may be reported. Furthermore, lipid composition papers should incorporate elements of yeartoyear, environmental, and/ or cultivar variations through use of appropriate statistical analyses.