Hydrocarbon productivities in different <Emphasis Type="Italic">Botryococcus</Emphasis> strains: comparative methods in product quantification

Six different strains of the green microalgae Botryococcus belonging to the A-race or B-race, accumulating alkadiene or botryococcene hydrocarbons, respectively, were compared for biomass and hydrocarbon productivities. Biomass productivity was assessed gravimetrically upon strain growth in the laboratory under defined conditions. Hydrocarbon productivities were measured by three different and independent experimental approaches, including density equilibrium of the intact cells and micro-colonies, spectrophotometric analysis of hydrocarbon extracts, and gravimetric quantitation of eluted hydrocarbons. All three hydrocarbon-quantitation methods yielded similar results for each of the strains examined. The B-race microalgae Botryococcus braunii var. Showa and Kawaguchi-1 constitutively accumulated botryococcene hydrocarbons equivalent to 30% and 20%, respectively, of their overall biomass. The A-race microalgae Botryococcus braunii, varieties Yamanaka, UTEX 2441 and UTEX LB572 constitutively accumulated alkadiene hydrocarbons ranging from 14% to 13% and 10% of their overall biomass, respectively. Botryococcus sudeticus (UTEX 2629), a morphologically different green microalga, had the lowest hydrocarbon accumulation, equal to about 3% of its overall biomass. Results validate the density equilibrium and spectrophotometric analysis methods in the quantitation of botryococcene-type hydrocarbons. These analytical advances will serve in the screening and selection of B. braunii and of other microalgae in efforts to identify those having a high hydrocarbon content for use in commercial applications.     

Botryococcus braunii: A Renewable Source of Hydrocarbons and Other Chemicals

ABSTRACT:?

Botryococcus braunii, a green colonial microalga, is an unusually rich renewable source of hydrocarbons and other chemicals. Hydrocarbons can constitute up to 75% of the dry mass of B. braunii. This review details the various facets of biotechnology of B. braunii, including its microbiology and physiology; production of hydrocarbons and other compounds by the alga; methods of culture; downstream recovery and processing of algal hydrocarbons; and cloning of the algal genes into other microorganisms. B. braunii converts simple inorganic compounds and sunlight to potential hydrocarbon fuels and feedstocks for the chemical industry. Microorganisms such as B. braunii can, in the long run, reduce our dependence on fossil fuels and because of this B. braunii continues to attract much attention.     

Growth and hydrocarbon production ofBotryococcus braunii immobilized in calcium alginate gel

Summary The colonial microalgaB. braunii, immobilized in calcium alginate beads, shows active photoautotrophic growth. Nevertheless, the rates of increase in cell number and, to a lesser extent, in biomass are substantially lower when compared to free cultures. Such features are related to steric contraints which occasion also the formation of large spherical colonies in the gel, showing an unsual mulberry organization. Some cracks due to the development of underlying colonies appear at the surface of the beads. Alga release remains low, however, during the cultures. EntrappedB. braunii retain the ability to produce extracellular hydrocarbons; the structure of the latter is not affected by immobilization but their relative abundances can undergo some variations. Entrapment leads to marked improvements in hydrocarbon production; decrease in growth rates is therefore associated, in alginate gel, with a still more pronounced diversion ofB. braunii metabolic activity towards hydrocarbon generation. It appears also that the improvements in hydrocarbon production, due to strain selection and to culture condition adjustment, obtained in free cultures, can be directly applied toB. braunii immobilized in alginate beads.     

The biosynthesis of long-chain hydrocarbons in the green alga Botryococcus braunii

The green colonial alga Botryococcus braunii has unusually high levels of hydrocarbons. Two distinct sites of hydrocarbon accumulation are present in the species: an internal pool present in cytoplasmic inclusions and an external pool in the trilaminar outer walls and associated globules. It is generally assumed that the hydrocarbons are produced within the cells and then excreted into the external pool to maintain the intracellular content at a normal value. Various feeding experiments showed, however, that the radioactivity of the external pool is much higher than the internal one. On the other hand, there was no decrease in the labelling of internal hydrocarbons in chase experiments. Therefore, an excretory process apparently does not take place in B. braunii. The outer wall, therefore, is the main site of hydrocarbon accumulation and also the place where the bulk of B. braunii hydrocarbons are produced. The outer wall also is involved in the matrix of colony formation and the above findings account for the sharp decrease of hydrocarbon production which is associated with the loss of colonial habit. The cultures were also shown to be unable, under usual growth conditions, to catabolize their own hydrocarbons. Such a feature, along with the extracellular location of the main site of production, may account for the abnormally high content of hydrocarbons typical of B. braunii.     

Photosynthesis,growth and hydrocarbon production ofBotryococcus braunii immobilized by entrapment and adsorption in polyurethane foams

Summary Direct entrapment of the hydrocarbonrich algaBotryococcus braunii was examined using eleven polyurethane prepolymers. A high toxicity was observed in several foams. With five of the tested prepolymers, nevertheless, a large part of the algal population can survive entrapment and substantial photosynthetic capacity, ca. 40–60% relative to free controls, was retained one day after immobilization. However, prolonged batches under standard conditions revealed a long-term toxicity; as a result the photosynthetic capacity and hydrocarbon production of the entrapped cultures were strongly reduced relative to free controls. Immobilization ofB. braunii was also achieved, with a loading yield of ca. 70%, via adsorption on FHP 4000 and FHP 5000 foams. Subsequent batch cultures under shaken and airlift conditions revealed a substantial release, ca. 30% of free cells, at the end of the cultures. However, the release from these adsorbed cultures was no higher than from directly entrappedB. braunii. Furthermore, no toxic effects were noted in the adsorbed cultures; the showed active growth, high photosynthetic capacity and produced quite large amounts of hydrocarbons, the chemical structure and the relative abundance of which were not altered by immobilization. Taking into account cell leakage, it appears that adsorbed cultures exhibit a similar, and sometimes even higher metabolic activity than free controls; thus, under air-lift conditions, high biomass and hydrocarbon productivities can be achieved.     

Culture of the green microalga Botryococcus braunii Showa with LED irradiation eliminating violet light enhances hydrocarbon production and recovery

The green microalga Botryococcus braunii (B. braunii), race B, was cultured under light-emitting diode (LED) irradiation with and without violet light. This study examined the effect of violet light on hydrocarbon recovery and production in B. braunii. C34 botryococcene hydrocarbons were efficiently extracted by thermal pretreatments at lower temperatures when the alga was cultured without violet light. The hydrocarbon content was also higher (approximately 3%) in samples cultured without violet light. To elucidate the mechanism of effective hydrocarbon recovery and production, we examined structural components of the extracellular matrix (ECM). The amounts of extracellular carotenoids and water-soluble polymers extracted by thermal pretreatment from the ECM were decreased when the alga was cultured without violet light. These results indicate that LED irradiation without violet light is more effective for hydrocarbon recovery and production in B. braunii. Furthermore, structural ECM components are closely involved in hydrocarbon recovery and production in B. braunii.     

Genome size and phylogenetic analysis of the A and L races of <Emphasis Type="Italic">Botryococcus braunii</Emphasis>

Botryococcus braunii (Chlorophyta, Botryococcaceae) is a colony-forming green microalga that produces large amounts of liquid hydrocarbons, which can be converted into transportation fuels. There are three different races of B. braunii, A, B, and L, that are distinguished based on the type of hydrocarbon each produces. Each race also has many strains that are distinguished by the location from which they were collected. While B. braunii has been well studied for the chemistry of the hydrocarbon production, very little is known about the molecular biology of B. braunii. To begin to address this problem, we determined the genome size of the A race, Yamanaka strain, and the L race, Songkla Nakarin strain, of B. braunii. Flow cytometry analysis indicates that the A race of B. braunii has a genome size of 166.0 ± 0.4 Mb, while the L race has a substantially larger genome size at 211.3 ± 1.7 Mb. We also used phylogenetic analysis with the nuclear small subunit (18S) rRNA gene to classify strains of the A and B races that have not yet been compared evolutionarily to previously published B. braunii phylogenetics. The analysis suggests that the evolutionary relationship between B. braunii races is correlated with the type of liquid hydrocarbon they produce.     

Mechanism of non-isoprenoid hydrocarbon biosynthesis in Botryococcus braunii

The green unicellular alga Botryococcus braunii shows unusually high concentrations of non-isoprenoid very long chain hydrocarbons. The structure of such hydrocarbons, the relative efficiency of various long chain fatty acids as precursors, the relationship between fatty acid and hydrocarbon concentrations (over the different physiological stages of the alga achieved during batch cultures) and the preferential localization of fatty acids lead to the conclusion that all the major non-isoprenoid hydrocarbons of B. braunii derive from the same direct precursor, oleic acid. Feeding experiments, using doubly labelled oleic acid, show that the whole carbon chain of the latter is incorporated into final hydrocarbons; accordingly such compounds do not originate from a head-to-head condensation mechanism with oleic acid acting as donor. Various features (regarding chiefly the systematic occurrence of a terminal double bond in B. braunii hydrocarbon, their close specific activities after feeding and the large inhibition in their production achieved using dithioerythritol) show that the biosynthesis of B. braunii hydrocarbons probably takes place via an elongation-decarboxylation mechanism related to that operating in some higher plants.     

Improved algal oil production from Botryococcus braunii by feeding nitrate and phosphate in an airlift bioreactor

To improve biomass and microalgal oil production of Botryococcus braunii, fed‐batch culture was investigated in an airlift photobioreactor. The optimal feeding time of the fed‐batch culture was after 15 days of cultivation, where 1.82 g/L of the microalgal biomass was obtained in the batch culture. Nitrate nutrient was the restrictive factor for the fed‐batch cultivation while phosphate nutrient with high concentration did not affect the microalgal growth. The optimal mole ratio of nitrate to phosphate was 34.7:1, where nitrate concentration reached the initial level and phosphate concentration was one quarter of its initial level. With one feeding, the biomass of B. braunii reached 2.56 g/L after 18 days. Two feedings in 2‐day interval enhanced the biomass production up to 2.87 g/L after 19 days of cultivation. The hydrocarbon content in dry biomass of B. braunii kept at high level of 64.3% w/w. Compared with the batch culture, biomass production and hydrocarbon productivity of B. braunii were greatly improved by the strategic fed‐batch cultivation.     

Echinenone production of a dark red-coloured strain of Botryococcus braunii

Echinenone has been used as an edible orange pigment, antioxidant and provitamin A. An echinenone-accumulating strain, BOT-20, of Botryococcus braunii was isolated from freshwater environments in Japan. The B. braunii BOT-20 strain is different from other strains of B. braunii, as it appeared dark red during its growth in the laboratory culture as opposed to green. The biomass of the strain was 1.9?g?L^?1 at 1?month after cultivation. The n-hexane/acetone (3:1, v/v) extract of the strain was 45.5% of the dry biomass weight and consisted of carotenoids (92%, of which 73% was echinenone) and hydrocarbons (8%). The echinenone content was 30.5% of the dry biomass weight, and production was 630?mg?L^?1. Hydrocarbons comprised only 3.7% of the total dry biomass weight. The main component of hydrocarbon was an analogue of botryococene by ¹H and ¹³C NMR. With high values of echinenone content and production, the B. braunii strain BOT-20 is expected to be a new bioresource for the commercial production of echinenone.     

Lipid and hydrocarbon production byBotryococcus spp. under nitrogen limitation and anaerobiosis

The production of lipids and hydrocarbons in batch cultures of the algaeBotryococcus braunii andB. protuberans has been studied with respect to nitrogen limitation under aerobic and anaerobic conditions. Nitrogen deficiency significantly decreased the dry weight, chlorophylla and protein contents but the amounts of carotenoids, carbohydrates and lipids increased in both the species. Nitrogen starvation gave a 1.6-fold increase in lipid content. Anaerobiosis under nitrogen deficient conditions gave greater lipid production than anaerobiosis in nitrogen supplemented medium. Under nitrogen deficiency, the hydrocarbon fraction increased and the polar lipids decreased. Anaerobiosis induced hydrocarbon synthesis more significantly than nitrogen deficiency but decreased other non-polar and polar lipids.     

The effect of nutrients and environmental conditions on biomass and oil production in Botryococcus braunii Race B strains

The green alga Botryococcus braunii is widely recognized as a source of non-fossil oil. However, limitations in Botryococcus biomass production hamper its commercial exploitation. This study examines the effects of nutrients (nitrogen and iron) and environmental conditions (temperature, light intensity and photoperiod) on biomass and oil production in two B. braunii Race B strains, Kossou-4 and Overjuyo-3. The highest biomass and oil production were obtained at a nitrogen concentration of 750 mg l^?1, iron concentration of 6 mg l^?1, at 25°C and at 135 µmol photons m^?2 s^?1 with a photoperiod of 16 h light:8 h darkness. Culturing the strains in Blue-green (BG11) medium containing optimized nutrients under optimal conditions resulted in an up to ~10.6-fold increase in biomass. In Kossou-4 and Overjuyo-3 strains, biomass increased from 1.647 g 10 l^?1 and 3.137 g 10 l^?1 respectively in normal BG11 medium to 17.390 g 10 l^?1 and 21.721 g 10 l^?1 in optimized BG11 media and growth conditions. This was accompanied by ~8–10.5-fold increase in oil production compared with that in normal BG11 medium. Oil (0.324 g 10 l^?1 and 0.211 g 10 l^?1) was produced in normal BG11 medium in Kossou-4 and Overjuyo-3 strains respectively, compared with 2.642 g 10 l^?1 (Kossou-4) and 2.206 g 10 l^?1 (Overjuyo-3) in modified BG11 media under optimized conditions. Therefore, optimization of nutrients and environmental conditions can increase biomass and oil production in the two strains of B. braunii.     

Hydrocarbon production in Anacystis montana and Botryococcus braunii

The production of labelled aliphatic hydrocarbons in Anacystis montana and Botryococcus braunii has been studied using Na₂CO₃ [¹⁴C] as a carbon source. The major hydrocarbon produced by A. montana is pentadecane (ca 93%) accompanied by a pentadecene (ca 4%) and other hydrocarbons in the range C₁₃-C₁₇. Long chain (C₂₁-C ₃₃) hydrocarbons could not be detected in this organism. The variety of unsaturated hydrocarbons (C₂₅-C₃₁) previously reported in Botryococcus braunii is confirmed and contrasts with the synthesis of unsaturated C₁₇ hydrocarbons only, in axenic cultures prepared from single cell isolates of this colonial alga.     

富油微藻布朗葡萄藻分子生态学研究进展

分子生态学是研究生命系统与环境系统相互作用机理及其分子机制的科学,可以从宏观和微观结合的角度真实反映生态现象的本质。简述产烃布朗葡萄藻形态与化学种等生理生态特征的基础上,综述了近年来国内外布朗葡萄藻分子生态学研究的新进展,主要包括分子系统发育学及其与化学种、基因组、地理来源等之间的关系。经典分类学上,关于布朗葡萄藻属于绿藻门(Chlorophyta)还是黄藻门(Xanthophyta)存在争议,而基于18S核糖体核糖核酸(18S ribosomal ribonucleic acid,18S rRNA)序列的分子系统发育学研究结果将布朗葡萄藻界定为绿藻门、共球藻纲(Trebouxiophyceae)。依据藻株的产烃种类和化学结构特征,可将布朗葡萄藻划分为A、B和L 3个化学种,而布朗葡萄藻的分子系统学进化关系与化学种间高度统一。在基因组大小上,位于同一大亚聚群中的化学种B与L间却存在明显差异,而进化关系较远的化学种B与A间则更相近。不同地理来源布朗葡萄藻的18S rRNA序列和内部转录间隔区(internal transcribed spacer,ITS)多态性较高,提示不同地缘藻株间存有较高的遗传多样性。探讨了布朗葡萄藻分子生态学研究尚待解决的问题,并对今后相关研究做了展望。     

Interactions of Botryococcus braunii Cultures with Bacterial Biofilms

Unicellular microalgae generally grow in the presence of bacteria, particularly when they are farmed massively. This study analyzes the bacteria associated with mass culture of Botryococcus braunii: both the planktonic bacteria in the water column and those forming biofilms adhered to the surface of the microalgal cells (∼10⁷–10⁸ culturable cells per gram microalgae). Furthermore, we identified the culturable bacteria forming a biofilm in the microalgal cells by 16S rDNA sequencing. At least eight different culturable species of bacteria were detected in the biofilm and were evaluated for the presence of quorum-sensing signals in these bacteria. Few studies have considered the implications of this phenomenon as regards the interaction between bacteria and microalgae. Production of C4-AHL and C6-AHL were detected in two species, Pseudomonas sp. and Rhizobium sp., which are present in the bacterial biofilm associated with B. braunii. This type of signal was not detected in the planktonic bacteria isolated from the water. We also noted that the bacterium, Rhizobium sp., acted as a probiotic bacterium and significantly encouraged the growth of B. braunii. A direct application of these beneficial bacteria associated with B. braunii could be, to use them like inoculants for large-scale microalgal cultures. They could optimize biomass production by enhancing growth, particularly in this microalga that has a low growth rate.     

Stimulation of Plant Growth and Drought Tolerance by Native Microorganisms (AM Fungi and Bacteria) from Dry Environments: Mechanisms Related to Bacterial Effectiveness

In this study we tested whether rhizosphere microorganisms can increase drought tolerance to plants growing under water-limitation conditions. Three indigenous bacterial strains isolated from droughted soil and identified as Pseudomonas putida, Pseudomonas sp., and Bacillus megaterium were able to stimulate plant growth under dry conditions. When the bacteria were grown in axenic culture at increasing osmotic stress caused by polyethylene glycol (PEG) levels (from 0 to 60%) they showed osmotic tolerance and only Pseudomonas sp. decreased indol acetic acid (IAA) production concomitantly with an increase of osmotic stress (PEG) in the medium. P. putida and B. megaterium exhibited the highest osmotic tolerance and both strains also showed increased proline content, involved in osmotic cellular adaptation, as much as increased osmotic stress caused by NaCl supply. These bacteria seem to have developed mechanisms to cope with drought stress. The increase in IAA production by P. putida and B. megaterium at a PEG concentration of 60% is an indication of bacterial resistance to drought. Their inoculation increased shoot and root biomass and water content under drought conditions. Bacterial IAA production under stressed conditions may explain their effectiveness in promoting plant growth and shoot water content increasing plant drought tolerance. B. megaterium was the most efficient bacteria under drought (in successive harvests) either applied alone or associated with the autochthonous arbuscular mycorrhizal fungi Glomus coronatum, Glomus constrictum or Glomus claroideum. B. megaterium colonized the rhizosphere and endorhizosphere zone. We can say, therefore, that microbial activities of adapted strains represent a positive effect on plant development under drought conditions.     

Production of a Gaseous Saturated-hydrocarbon Mixture by Rhizopus japonicus under Aerobic Conditions

The microbial production, by the genus Rhizopus, of a gaseous saturated-hydrocarbon mixture was studied under aerobic conditions. Rhizopus strains, comprising 13 strains of 9 species, were tested as to their ability to produce a gaseous hydrocarbon mixture. Except for one strain, all the strains tested produced more than two kinds of gaseous hydrocarbons simultaneously when grown in nutrient broth containing glucose. Rhizopus japonicus IFO 4758 was selected as being typical of these producers of mixed gaseous hydrocarbons. When this organism was cultivated in a synthetic medium supplemented with l-cysteine under aerobic conditions, the maximum production of the total gaseous hydrocarbon mixture reached ca. 10 nl/ml culture broth/hr. The gaseous hydrocarbon mixture produced was composed mainly of paraffin hydrocarbons, i.e., ca. 74% pentane, ca. 16% propane and a trace amount of methane. The ratios of saturated to unsaturated, and even to odd number hydrocarbons produced by this fungus were 95 : 5 and 90: 10, respectively. The biosynthetic pathways for the production of these gases are discussed in comparison with the biosynthetic pathways for ethylene and isobutene in microorganisms.     

Effects of carbon source on growth and morphology of <Emphasis Type="Italic">Botryococcus braunii</Emphasis>

The green colonial alga Botryococcus braunii is characterized by the ability to produce and accumulate large amounts of hydrocarbons. We isolated and established an axenic clonal strain of B. braunii B70 and investigated the effects of organic carbon sources, including glucose, mannose, fructose, galactose, or acetate, on growth under light and dark conditions. This algal strain had the capacity to grow photo-, mixo-, or heterotrophically. Growth was promoted substantially following exposure of the algae to glucose or mannose under light exposure. Cells could grow under continuous darkness with glucose or mannose. In the presence of glucose under light or dark conditions, cell and colony size, and the intracellular granules containing oil, were markedly larger than those cultured without glucose.     

Botryococcus braunii: a rich source for hydrocarbons and related ether lipids

This paper presents a review on Botryococcus braunii, a cosmopolitan green colonial microalga characterised by a considerable production of lipids, notably hydrocarbons. Strains like wild populations of this alga differ in the type of hydrocarbons they synthesise and accumulate: (1) n-alkadienes and trienes, (2) triterpenoid botryococcenes and methylated squalenes, or (3) a tetraterpenoid, lycopadiene. In addition to hydrocarbons and some classic lipids, these algae produce numerous series of characteristic ether lipids closely related to hydrocarbons. This review covers the algal biodiversity, the chemical structures and biosynthesis of hydrocarbons and ether lipids and the biotechnological studies related to hydrocarbon production.