School of Biological Sciences, Royal Holloway University of London, Egham, Surrey TW20 0EX, United Kingdom.
Fraunhofer Chile Research, Las Condes, Santiago 7550296, Chile.
Proc Natl Acad Sci U S A. 2017 Oct 10;114(41):10876-10881. doi: 10.1073/pnas.1708349114. Epub 2017 Sep 25.
Ketocarotenoids are high-value pigments used commercially across multiple industrial sectors as colorants and supplements. Chemical synthesis using petrochemical-derived precursors remains the production method of choice. Aquaculture is an example where ketocarotenoid supplementation of feed is necessary to achieve product viability. The biosynthesis of ketocarotenoids, such as canthaxanthin, phoenicoxanthin, or astaxanthin in plants is rare. In the present study, complex engineering of the carotenoid pathway has been performed to produce high-value ketocarotenoids in tomato fruit (3.0 mg/g dry weight). The strategy adopted involved pathway extension beyond β-carotene through the expression of the β-carotene hydroxylase () and oxyxgenase () from sp. in tomato fruit, followed by β-carotene enhancement through the introgression of a lycopene β-cyclase (β-) allele from a background. Detailed biochemical analysis, carried out using chromatographic, UV/VIS, and MS approaches, identified the predominant carotenoid as fatty acid (C14:0 and C16:0) esters of phoenicoxanthin, present in the stereoisomer configuration. Under a field-like environment with low resource input, scalability was shown with the potential to deliver 23 kg of ketocarotenoid/hectare. To illustrate the potential of this "generally recognized as safe" material with minimal, low-energy bioprocessing, two independent aquaculture trials were performed. The plant-based feeds developed were more efficient than the synthetic feed to color trout flesh (up to twofold increase in the retention of the main ketocarotenoids in the fish fillets). This achievement has the potential to create a new paradigm in the renewable production of economically competitive feed additives for the aquaculture industry and beyond.
类胡萝卜素酮是一种高价值的色素,在多个工业领域被广泛用作着色剂和补充剂。使用石油化工衍生前体的化学合成仍然是首选的生产方法。水产养殖就是一个需要通过饲料补充类胡萝卜素酮来实现产品可行性的例子。在植物中,如角黄素、叶黄素或虾青素等类胡萝卜素酮的生物合成是罕见的。在本研究中,通过对类胡萝卜素途径进行复杂的工程改造,在番茄果实中(干重 3.0 毫克/克)生产高价值的类胡萝卜素酮。所采用的策略涉及通过表达来自 sp.的 β-胡萝卜素羟化酶()和加氧酶(),将 β-胡萝卜素途径延伸到酮类,然后通过从 背景中导入番茄红素 β-环化酶(β-)等位基因来增强 β-胡萝卜素。使用色谱、UV/VIS 和 MS 方法进行的详细生化分析,确定主要类胡萝卜素为叶黄素的脂肪酸(C14:0 和 C16:0)酯,呈(C14:0 和 C16:0)酯,呈 立体异构体构型。在低资源投入的田间环境下,展示了可扩展性,有可能实现每公顷 23 公斤的类胡萝卜素酮。为了说明这种“普遍认为安全”的材料的潜力,其最小的、低能量的生物加工可以带来经济效益,进行了两项独立的水产养殖试验。所开发的植物性饲料比合成饲料更有效地给鳟鱼肉着色(在鱼片中主要类胡萝卜素的保留率提高了一倍)。这一成就有可能在可再生生产经济上有竞争力的水产养殖行业及其他行业的饲料添加剂方面创造一个新的范例。