A novel double-layered photobioreactor for simultaneous Haematococcus pluvialis cell growth and astaxanthin accumulation

This study proposes a novel double-region photobioreactor to simplify the commercial two-stage process of astaxanthin production by the cultivation of Haematococcus pluvialis. The feasibility of the double-region photobioreactor has been investigated and found to achieve high biomass yield in the inner core region and simultaneous astaxanthin accumulation in the outer jacket region. Among many environmental factors, light condition and nitrate level were manipulated for selective cell growth and astaxanthin production. In the outer jacket region, efficient astaxanthin production was accomplished by excessive irradiation (770+/-20 microE m(-2)s(-1)) and nitrate starvation, resulting in a dramatic increase of astaxanthin productivity (357 mg l(-1)). Meanwhile, attenuated light energy (40+/-3 microE m(-2)s(-1)) and sufficient nitrates were supplied to the vegetative cells in the inner core region, which continued to grow to a high cell concentration of 4.0 x 10(5) cells ml(-1). The sequential batch run was performed by utilizing the high-density vegetative cells as inoculum for the next batch run. The cultivation results exhibited similar trends as the previous run, reaching high cell density (4.3 x 10(5) cells ml(-1)) in the inner core region and high astaxanthin content (5.79% on a dry weight basis) in the outer jacket region. The present study indicates that the double-region photobioreactor and its method of operation possess a good potential for commercial production of astaxanthin by H. pluvialis.     

Separation and identification of astaxanthin esters and chlorophylls in Haematococcus lacustris by HPLC

Summary An isocratic reverse-phase high performance liquid chromatographic method was developed for the separation of carotenoids and chlorophylls from extracts of Haematococcus lacustris. Astaxanthin monoesters are the principal carotenoids in Haematococcus lacustris. Five astaxanthin monoesters, which accounted for 79% of the total carotenoids, were identified and the individual contents were determined by HPLC to be 7.3, 24.9, 6.1, 49.4 and 12.3% of the total astaxanthin monoesters, respectively. The maximum absorption wavelengths of the five astaxanthin monoesters in the mobile phase were all 479 nm, and that of free astaxanthin, the main saponification product of the astaxanthin esters, was 478 nm.     

Reduction of photosynthetic apparatus plays a key role in survival of the microalga Haematococcus pluvialis (Chlorophyceae) at freezing temperatures

The microalga Haematococcus pluvialis is a biotechnologically important microorganism producing a ketocarotenoid astaxanthin. Haematococcus exists either as metabolically active vegetative cells with a high chlorophyll content or astaxanthin-rich haematocysts (aplanospores). This microalga featuring outstanding tolerance to a wide range of adverse conditions is a highly suitable model for studies of freezing tolerance in phototrophs. The retention of H. pluvialis cell viability after freezing–thawing is ascribed to elevated antioxidant enzyme activity and high ketocarotenoid content. However, we report that only haematocysts characterized by a lower photosynthetic activity were resistant to freezing–thawing even without cryoprotectant addition. The key factors of haematocyst freezing tolerance were assumed to be a low water content, rigid cell walls, reduction of the membranous structures, photosynthesis downregulation, and low chlorophyll content. Collectively, viability of Haematoccus after freezing–thawing can be improved by forcing the transition of vegetative cells to freeze-tolerant haematocysts before freezing.

     

Isolation and proteomic analysis [corrected] of cell wall-deficient Haematococcus pluvialis mutants

The green alga Haematococcus pluvialis has a plant-like cell wall consisting of glycoproteins and cellulose that is modified during the cell cycle and under various conditions. These features allow Haematococcus to be used as a model organism for studying cell wall biology. Development of the Haematococcus model is hampered by the absence of mutants that could provide insight into the biosynthesis and assembly of wall components. Haematococcus mutants (WM#537 and WM#2978) (WM--wall mutant) with defective cell walls were obtained by chemical mutagenesis. WM#537 features a secondary wall of considerably reduced thickness, whereas WM#2978 possesses a somewhat reduced secondary wall with little intervening space between the wall and plasmalemma. 2-DE revealed that a majority of the cell wall proteins were present in the wild-type and mutant cell walls throughout the cell cycle. PMF identified 55 wall protein orthologs from these strains, including a subset of induced proteins known to be involved in wall construction, remodeling, and defense. Down-regulation of certain wall proteins in the two mutants was associated with the wall defects, whereas overexpression of other proteins may have compensated for the defective walls in the two mutants.     

小球藻联产油脂和虾青素的基元模式分析

构建了包含虾青素合成途径的小球藻代谢网络模型,集成文献报道同位素标定的小球藻代谢通量数据,估算了胞内代谢通量分布。在正常和缺氮培养条件下,虾青素的代谢通量分别为0.38和0.35。计算得到基元模式共640条,通过最大熵原理算法求取了正常培养和缺氮培养条件下的基元模式概率。存在4条关键基元模式,在2种培养条件下,其基元模式概率之和分别为60.95%和77.53%。虾青素的最大理论合成产率为11.27%,但是这4条关键基元模式并不包括虾青素的合成反应。     

Anticancer effects and lysosomal acidification in A549 cells by Astaxanthin from Haematococcus lacustris

Astaxanthin (AXN) is known to have health benefits by epidemiological studies. Therefore, it is of interest to assess the effect of AXN (derived from indigenous unicellular green alga Haematococcus lacustris) to modulate cell cycle arrest, lysosomal acidification and eventually apoptosis using in vitro in A549 lung cancer cells. Natural extracts of astaxanthin were obtained by standardized methods as reported earlier and characterized by standard HPLC and MS. Treatment of A549 cells with AXN (purified fraction) showed significant reduction in cell viability (about 50%) as compared to crude extract at 50µM concentration. Thus, we show the anticancer effects and lysosomal acidification in A549 cells by Astaxanthin from Haematococcus lacustris for further consideration. Together, our results demonstrated the anticancer potential of AXN from Haematococcus lacustris, which is found to be mediated via its ability to induce cell cycle arrest, lysosomal acidification and apoptotic induction.     

Carotenogenesis in the green alga Haematococcus pluvialis: Cellular physiology and stress response

The unicellular green alga Haematococcus pluvialis Flotow has recently aroused considerable interest due to its capacity to amass large amounts of the ketocarotenoid astaxanthin (3,3'-dihydroxy- β , β -carotene-4,4'-dione), widely used commercially to color flesh of salmon. Astaxanthin accumulation in Haematococcus is induced by a variety of environmental stresses which limit cell growth in the presence of light. This is accompanied by a remarkable morphological and biochemical 'transformation' from green motile cells into inert red cysts. In recent years we have studied this transformation process from several aspects: defining conditions governing pigment accumulation, working out the biosynthetic pathway of astaxanthin accumulation and questioning the possible function of this secondary ketocarotenoid in protecting Haematococcus cells against oxidative damage. Our results suggest that astaxanthin synthesis proceeds via cantaxanthin and that this exceptional stress response is mediated by reactive oxygen species (ROS) through a mechanism which is not yet understood. The results do not support in vivo chemical quenching of ROS by the pigment, although in vitro it was shown to quench radicals very efficiently. The finding that most of the pigment produced is esterified and deposited in lipid globules outside the chloroplast further supports this assumption. We have suggested that astaxanthin is the by-product of a defense mechanism rather than the defending substance itself, although at this stage one cannot rule out other protective mechanisms. Further work is required for complete understanding of this transformation process. It is suggested that Haematococcus may serve as a simple model system to study response to oxidative stress and mechanisms evolved to cope with this harmful situation.     

利用雨生红球藻表达系统高通量筛选活力提高的阿特拉津氯水解酶突变子

阿特拉津氯水解酶定向改造的关键是开发一种廉价的、表型改变明显的高通量筛选方法。利用高错误倾向PCR和DNA洗牌相结合的突变方法,对来源于假单胞菌ADP和节杆菌AD1的阿特拉津氯水解酶基因进行随机突变,以雨生红球藻为受体、以阿特拉津为选择压力对突变文库进行高通量筛选。筛选到的12个突变子序列分析显示,突变均为点替换,位点分散在全基因上,是在高错误倾向PCR及DNA洗牌过程中逐渐累积形成的。酶活力分析显示,突变子的酶活力均高于野生株,在添加1.0 mg/L阿特拉津培养液中的活力是野生株的1.9~3.6倍,在添     

褪黑素对非生物胁迫下雨生红球藻中虾青素积累的影响

以雨生红球藻Haematococcus pluvialis LUGU株为研究对象, 研究在高光照和缺氮胁迫条件下, 添加不同浓度褪黑素(melatonin, MLT)对雨生红球藻生长、虾青素积累、活性氧(ROS)、信号分子及dxs基因表达量的影响。结果表明, 外源添加10 μmol/L MLT可有效提高藻细胞中虾青素的含量, 最高可达31.32 mg/g, 是对照组(13.27 mg/g)的2.36倍; 抑制了细胞内ROS水平, 上调了信号分子一氧化氮(NO)和水杨酸(SA)的含量; 此外, dxs基因表达水平比对照组明显提高, 最高达11.3倍。研究表明, 在非生物胁迫条件下, 雨生红球藻中虾青素的大量积累可能与外源MLT调控细胞内ROS、信号分子及基因表达有关。     

Haematococcus as a promising cell factory to produce recombinant pharmaceutical proteins

The need for recombinant pharmaceutical proteins has urged scientists all over the world to search for better protein expression systems which have higher capabilities and flexibilities. Although a number of protein expression systems are now available, no system is ideal and different systems lack specific properties. Here, microalga Haematococcus is discussed as a new protein expression system which merits cheap growth medium, fast growth rate, ease of manipulation and scale-up, ease of transformation, potential of exploiting in bioreactors and ability to exert post-translational modifications to the proteins. This green single-cell plant has favorable biological and biotechnological features for production of remarkable yields of recombinant proteins with high functionality. In this review article, we highlight the favorable biotechnological characteristics of Haematococcus for lowering costs and facilitating scale-up of recombinant protein production along with its superior biological features for genetic engineering.     

Screening and characterization of astaxanthin-hyperproducing mutants of Haematococcus pluvialis

Haematococcus pluvialis was mutated by UV or ethyl methanesulphonate. Mutants resistant to nicotine, diphenylamine, fluridone or norflurazon were then selected. Several nicotine-resistant mutants showed increased (1.9% to 2.5% vs. 1.2% w/w) astaxanthin production. Mutants maintained high astaxanthin production over 4 months of repeated culture.     

雨生红球藻质体球滴结构蛋白基因的克隆与原核表达

叶绿体或者有色体中的质体球滴结构(Plastoglobules)是多数植物的类胡萝卜素等次生代谢产物积累的场所,但在能大量积累虾青素的雨生红球藻中,这个结构一直没有得到确认。通过透射电子显微镜观察发现雨生红球藻的质体内确切存在plastoglobules结构;并通过RT-PCR结合RACE技术,从雨生红球藻cDNA文库中克隆到了与编码plastoglobules的结构蛋白(Plastoglobulin)具有高度同源性的基因序列全长,称做Hpgp基因;该基因的表达产物称之为雨生红球藻质体球滴蛋白(HPGP;Haematococcus plastoglobules pro-tein);并进一步利用原核表达系统将该编码基因进行原核诱导表达,用His-Tag蛋白分离纯化系统纯化到了目标蛋白,并用该His-Tag融合蛋白为抗原免疫实验兔,制备到了相应的一抗抗体,为下一步对该蛋白的功能阐明以及雨生红球藻的虾青素积累机制研究提供重要的基础。     

Microalgae as sources of high added-value compounds--a brief review of recent work

Microalgae have found commercial applications as natural sources of valuable macromolecules, including carotenoids, long-chain polyunsaturated fatty acids, and phycocolloids. As photoautotrophs, their simple growth requirements make them attractive for bioprocesses aimed at producing high added-value compounds that are in large demand by the pharmaceutical market. A few compounds synthesized by microalgae have indeed proven to possess anti-inflammatory, antiviral, antimicrobial, and antitumoral features; astaxanthin, a known antioxidant produced by Haematococcus pluvialis, is an illustrative example with important anti-inflammatory and antitumoral roles. From a chemical standpoint, several such compounds are polysaccharides or long chain fatty acids, where the latter can be either saturated or unsaturated. Additionally, their chemical structures are often atypical, whereas their concentrations can exceed those found in many other natural sources. The productivity and biochemical composition of microalgae depend strongly on the mode of cultivation, medium composition, and nutrient profile. Consequently, numerous efforts aimed at elucidating the practical impacts of the aforementioned parameters have been developed. This review accordingly covers the knowledge produced in the last two decades on the uses of microalgae to obtain physiologically active compounds, and on the optimization of the underlying production and purification processes. It also identifies major gaps and opportunities in this field that should be addressed or exploited in the near future.     

雨生红球藻虾青素合成研究进展

虾青素是一种重要的次级类胡萝卜素,具有高活性的抗氧化功能,广泛应用于食品保健、医药、水产养殖等领域。雨生红球藻是一种在胁迫条件下能够大量积累虾青素的微藻。文中回顾了雨生红球藻虾青素的生物合成研究的进展,包括虾青素生物合成的诱导与调控、虾青素合成与光合作用及脂类代谢的关系等研究现状。     

雨生红球藻(Haematococcus pluvialis)的光谱特性研究

实验测定了雨生红球藻不同生长阶段的色素组成,吸收光谱,荧光光谱,并对其进行了分析。结果表明,用490nm波长激发时,雨生红球藻在绿色细胞阶段存在710nm和730nm附近的长波长荧光发射峰,而在红色细胞阶段仅存在730nm的长波长荧光发射峰,预示着雨生红球藻不同生长阶段在PSⅠ结构,组成,及其色素蛋白的排布等方面有很大差异。     

Agricultural fertilizers as economical alternative for cultivation of Haematococcus pluvialis

A Haematococcus pluvialis strain isolated from the ruins of Ephesus in Turkey was investigated as regards its adaptation to laboratory conditions and maximum growth rate. In the first stage of the experiment, the growth of H. pluvialis was compared in common culture media. Furthermore, in an effort to minimize the culture costs, the second stage of the experiment compared the growth rate in the culture medium selected in the first stage with that in commercial plant fertilizers. The results demonstrated that the maximum cell concentration of 0.90 g/l, corresponding to a growth rate of 0.150 d(-1), was found with an N-P-K 20:20:20 fertilizer under a light intensity of 75 micromol photons m(-2) s(-1) on the 12th day of cultivation.     

Oxidative stress modulates astaxanthin synthesis in Haematococcus pluvialis

Journal of Applied Phycology - Astaxanthin, a carotenoid with potent antioxidant effects, is produced by the green alga Haematococcus pluvialis in response to stressful environmental conditions....     

On the relative efficiency of two- vs. one-stage production of astaxanthin by the green alga Haematococcus pluvialis

Haematococcus pluvialis under stress conditions overproduces the valuable red ketocarotenoid astaxanthin. Two proposed strategies for commercial production are under current analysis. One separates in time the production of biomass (optimal growth, green stage) and pigment (permanent stress, red stage), while the other uses an approach based on continuous culture under limiting stress at steady state. The productivities, efficiencies and yields for the pigment accumulation in each case have been compared and analyzed in terms of the algal basic physiology. The two-stage system indoors yields a richer astaxanthin product (4% of dry biomass) with a final astaxanthin productivity of 11.5 mg L(-1) day(-1), is more readily upscalable and amenable to outdoors production. Furthermore, each stage can be optimized for green biomass growth and red pigment accumulation by adjusting independently the respective ratio of effective irradiance to cell density. We conclude that the two-stage system performs better (by a factor of 2.5-5) than the one-stage system, and the former is best fit in an efficient mass production setup.     

Secondary ketocarotenoid astaxanthin biosynthesis in algae: a multifunctional response to stress

Under stressful environments, many green algae such as Haematococcus pluvialis accumulate secondary ketocarotenoids such as canthaxanthin and astaxanthin. The carotenogenesis, responsible for natural phenomena such as red snows, generally accompanies larger metabolic changes as well as morphological modifications, i.e., the conversion of the green flagellated macrozoids into large red cysts. Astaxanthin accumulation constitutes a convenient way to store energy and carbon, which will be used for further synthesis under less stressful conditions. Besides this, the presence of high amount of astaxanthin enhances the cell resistance to oxidative stress generated by unfavorable environmental conditions including excess light, UV-B irradiation, and nutrition stress and, therefore, confers a higher survival capacity to the cells. This better resistance results from the quenching of oxygen atoms for the synthesis itself as well as from the antioxidant properties of the astaxanthin molecules. Therefore, astaxanthin synthesis corresponds to a multifunctional response to stress. In this contribution, the various biochemical, genetic, and molecular data related to the biosynthesis of ketocarotenoids by Haematococcus pluvialis and other taxa are reviewed and compared. A tentative regulatory model of the biochemical network driving astaxanthin production is proposed.