Improvement of Medium Composition and Utilization of Mixotrophic Cultivation for Green and Blue Green Microalgae towards Biodiesel Production ()
2. Material and Methods
2.1. Algae Strains
The cyanobacterial strain Cyanobacterium aponicum and green microalgal species Chlorella sorokiniana and Scenedesmus acuminatus were obtained by prof. Gerd Klöck (Culture Collection of Algae at Hochschule Bremen University, Germany) was cultivated axenically as batch cultures in 500 ml Erlenmeyer flasks with 1% Wuxal medium +0.05% MgSO4·7H2O.
2.2. Culture System
The effect of different media namely Bold’s Basal Me-
Figure 1. Mixotrophic cultivation in Sixfors photobioreactor of tested microalgal species.
dium—BBM [11]. and optimized culture medium (OCM) as described by [12]; KNO3 (1 g/L), KH2PO4 (0.075 g/L), K2HPO4 (0.1 g/L), MgSO4·7H2O (0.5 g/L), Ca(NO3)2·4H2O (0.0625 g/L), FeSO4·7H2O (0.01 g/L), H3BO3 (0.00286 g/L), MnCl2·4H2O (0.00181 g/L), ZnCl2 (0.000105 g/L), Na2MoO4·2H2O (0.000039 g/L), CuSO4·5H2O (0.000079 g/L) and CoCl2 (0.000030 g/L). Were performed in 250 mL Erlenmeyer flasks containing 100 mL medium. The sterile flasks were inoculated with 10 mL of a standard inoculum and cultures were illuminated by tubular fluorescent lamps (PHILIPS Master TL-D 85 W/840). The light intensity at the surface of the culturing vessels was 100 µ mol photons m−2·s−1 with a photoperiod of 16:8 h light: dark at 25˚C ± 2˚C, agitated at 120 rpm in orbital incubator shaker.
2.3. Nitrogen Deficiency
For the nitrogen deficiency trial, the microalgal strains were inoculated in 500 mL Erlenmeyer flasks containing 200 OCM medium and incubated with 120 rpm agitation at 25˚C ± 2˚C under 100 µ mol photons m−2·s−1 light intensity with 16:8 h light and dark cycles for 7 days. The culture was then centrifuged at 4000 rpm g for 15 min using SORVALL RC PLUS roter SLA-3000). Cell pellets were re-suspended in OCM medium (a nitrogen-rich condition 100%) and OCM medium with different nitrogen-deficient concentrations −75%, −50%, −25%). The culture was incubated for 21 days. The dry biomass and lipid content were measured for three repetitive weeks. All the experiments were carried out in at least triplicates.
2.4. Mixotrophic Cultivation
Was carried out by two phase growth in closed system. In the first phase of culture of C.sorokiniana, S.acuminatus and C. aponicum were grown photoautotrophically in a 2 L vessel containing 1300 ml OCM medium, inoculated by 130 ml of an axenic culture, in exponential growth phase, The culture was kept at 25˚C ± 2˚C under 120 rpm agitation, 100 µ mol photons m−2·s−1 light intensity with 16:8 h light and dark cycles for 10 days. 250 ml of culture suspension was collected from the culture vessels and centrifuged at 5000 rpm for 15 min under sterilized condition micro algal pellets were placed into 500 ml culture flasks units of Sixfors photobioreactor INFORSAG-CH4103 Bottmingen Switzerland filled with OCM medium and enriched with different carbon sources types source [control (0 gL−1), glucose 0.3% (w/v), Sodium Acetate 0.3% (w/v), molasses hydroyzate 0.3% (v/v) and glycerol 0.3% (v/v)]. All were illuminated by tubular fluorescent lamps (PHILIPS Master TL-D 85 W/840). The light intensity at the surface of the culturing vessels was 100 µ mol photons m−2·s−1 with a photoperiod of 16:8 h light: dark. Stirring speed, internal temperature, pH and dissolved oxygen were kept constant in all photobioreactor units and it could be adjusted automatically (150 rpm, 25˚C ± 1˚C, 7 and 90% - 100% dissolved oxygen).
2.5. Preparation of Molasses Hydrolysate
Molasses of sugar cane was obtained from healthy shop food; it was hydrolyzed by the method described by [10]. Molasses was diluted with distilled water at a ratio of 1:1.5 (v/v). The diluted molasses was boiled for 20 min to remove precipitations by centrifugation at 6000 rpm for 2 min. The supernatant was saved for enzymatic hydrolysis by MAXINVERT200000MG β-invertase. The mixtures of molasses and invertase at a ratio of 2500:1 (w/w) were incubated at 60˚C for 24 h to generate molasses hydrolysate with more reducing sugar.
3. Analytical Procedure
3.1. Cell Counting
The microalgae cell number per ml of C. aponicum, C. sorokiniana and S. acuminatus were recorded daily and determined using Neubauer haemocytometer.
3.2. Biomass Assay
Were precisely determined with the dry cell weight method by filtering definite volume of the cultural broth in Whatman Gf6 glass fiber filter 47 mm under vacuum pump N820.3ft.40.18, washing twice with double distilled water and then drying the cell pellet at 105˚C till constant weigh.
3.3. Lipid Assay
Total neutral lipid content was quantitatively determined by a standard addition method, as described by [13]. Then fluorometric staining using Nile red, avoiding the association of traditional neutral lipids quantification methods to the fluorometric determination. After the optimization of instrument parameters and staining conditions, a linear correlation between the fluorescence intensity of each sample stained with the Nile red and its neutral lipids content was deduced with the standard addition method. The spectrofluorometric determinations were performed using a spectrofluorophotometer F-2500 (Hitachi). The fluorescence of the samples was always measured before and after Nile red addition, in order to subtract the intrinsic fluorescence value of the sample. Moreover, fluorescence intensity of Nile red-stained medium alone was subtracted. Samples of stained with Nile red and spiked with lipid standard. As lipid standard, a 10 mg/ml isopropanol solution of Triolein (1,2,3-Tri (cis-9-octadecenoyl)glycerol) (Sigma-Aldrich) was used. Stock solution of Nile red (9-diethylamino-5H-benzo[[a] phenoxa-] phenoxazine-5-one) was prepared dissolving 0.5 mg of Nile red per ml in acetone.
4. Results
According to data in Figure 2 it is obvious that OCM medium is significantly enhanced growth represented as cell number of three tested microalgal species for 22 days of incubation.
Further studying of the effect of two media type Bold’s medium and OCM (present in Table 1), revealed that OCM media significantly enhanced CDW of three tested microalgal species in comparison with Bold’s medium. The highest CDW was obtained on the 20th day of incubation for C. aponicum and C. sorokiniana, increasing 2.2 and 1.8 folds respectively, over Bold’s medium while the highest CDW for S. acuminatus was obtained on the 25th day by 1.5 folds increase compared to Bold’s medium at same day.
Similarly, OCM medium significantly enhanced lipid content for both S. acuminatus and C. aponicumon the 25th day of incubation by 7.6 and 5 folds respectively compared to Bold’s medium at same day. But the highest lipid content for C. sorokiniana was achieved under Bold’s medium on the 25th day by 1.8 fold increase. Meanwhile, S. acuminatus under OCM medium on the 25th day recorded a highly significant lipid content compared to other tested microalgae. With respect to lipid productivity generally, the highest values of lipid productivities was achieved at exponential phases for three tested microalgae; C. sorokiniana recorded the highest lipid productivity 13.8 mg·g−1·d−1 followed by S. acuminatus 9.1 mg·g−1·d−1 under Bold’s medium then they began to decline to its lowest values on the 25th day.
OCM medium was selected for further study in which four nitrogen descending levels at three repetitive weeks of second phase propagation and study their affect on CDW, lipid content and lipid productivity. All three tested microalgae recorded high CDW at 4th week of propagation under 100% nitrogen. S. acuminatus was the highest one 0.55 gL−1. While 25% nitrogen deficient medium significantly decreased CDW for all. On the other hand it significantly increased lipid content and lipid productivity for both C. sorokiniana and C. aponicumat 2nd week of re-propagation to 10.6 and 2.6 folds over control (100% nitrogen). In contrast S.acuminatus recorded the significant lipid content & productivity at 2nd week under recommended nitrogen dose in medium (100% N) by 4.4 folds over 25% deficient medium. It seems from data in Table 2 that lipid accumulation in algae cells vary according to species type, nitrogen level and incubation period.
Figure 3 shows effect of different types of carbon sources on CDW, lipid content and lipid productivity
(a)(b)(c)
Figure 2. Effect of two different media type (Basal Bold’s medium and optimized culture medium on growth of (a) Cyanobacterium aponicum; (b) Chlorella sorokiniana; (c) Scenedesmus acuminatus. Errors bars denote standard deviations among replicates.
(a)(b)(c)
Figure 3. Effect of different carbon sources on Biomass content (g·CDW·L−1), Lipid content (mg·g−1 CDW) and lipid productivities (mg·g−1·d−1) of (a) Cyanbacterium aponicum, (b) Chlorella sorokiniana and (c) Scenedes musacuminatus.
Table 1. Biomass content (g·CDW·L−1), Lipid content (mg·g−1 CDW) and lipid productivities (mg·g−1·d−1) of Cyanobacterium aponicum, Chlorella sorokiniana and Scenedesmus acuminatus under two different media types.
Table 2. Biomass content (g·CDW·L−1), Lipid content (mg·g−1 CDW) and lipid productivities (mg·L−1·d−1) of Cyanobacterium aponicum, Chlorella sorokiniana and Scenedesmus acuminatus under four levels of nitrogen deficiency of OCM medium.
during 12 days of incubation. Generally mixotrophic cultivation enhanced both CDW and lipid content for three microalgae but response of each one towards carbon source type markedly varied. S. acuminatus recorded highly significant CDW under 0.3% (v/v) glycerol medium 1.68 g·L−1 by increasing 3.4 folds over control while C. sorokiniana and C. aponicum recorded significant CDW under acetate medium 1.37 and 0.7 g·L−1 by increasing 2.9 and 5.8 folds respectively over control. C. aponicum exhibited no growth under 0.3% (v/v) glycerol medium.
Evaluation of lipid content revealed that C. sorokiniana recorded the highest lipid content under glycerol medium 64.3 mg·g−1 followed by S.acuminatus 52.8 mg·g−1 by increasing 5.2 and 2.8 folds respectively over control. In contrast C. aponicum reached its high lipid content under molasses medium 38.13 mg·g−1. The lowest lipid content was obtained by acetate medium for C. sorokiniana and C. aponicum with significant decrease of 1.2 and 1.8 folds under control medium.
With respect to lipid productivity C. sorokiniana recorded the highest value 5.4 mg·g−1·d−1 followed by S.acuminatus 4.4 mg·g−1·d−1 while C. aponicum showed 3.18 mg·g−1·d−1 under molasses medium.
5. Discussion
For biodiesel production, biomass productivity and lipid content play an important role from the economic point of view. The obtained results showed that OCM medium significantly improved growth of the three tested microalgae compared to Bold’s medium this finding is in accordance with [14], who reported that a proper medium design has shown to have a large impact on the growth capacity of Chlorella vulgaris cultures. On the other hand OCM medium enhanced lipid content for both S. acuminatus and C. aponicumat 25th day of incubation by 7.6 and 5 folds respectively this finding is in accordance [15], who mentioned that Lipid composition and productivity of microalgae depend on growth conditions such as medium composition, irradiance and temperature. With respect to the effect of nitrogen starvation on growth, lipid content and lipid productivity of C. aponicum, C. sorokiniana and S. acuminatus, the obtained results in (Table 2) showed that 25% nitrogen deficient medium significantly reduces the growth of three microalgae and markedlyincrease in lipid content of C. sorokiniana and C. aponicum. The reduction in growth by nitrogen deficiency may be explained by the observations of [16,17] who found that the decrease in pigment contents and photosynthesis are a typical response in nitrogen-limited algae. [18] made a comparative study between chlorophyll content of groups of green algae and cyanobacteria with different nitrogen concentrations; they showed that chlorophyll contents decreased with decreasing nitrogen concentrations. They also concluded that, with decreasing nitrogen levels, the chlorophyll contents of the cells dropped indicating a rapid reduction or even breakdown of the whole chloroplast apparatus and consequently decreasing of growth. The increase in lipid content observed in the present study as a result of nitrogen deficiency is in agreement with [18-20]. They reported that microalgae produce a considerable amount of lipid when exposed to environmental stress such as nitrogen limitation. The possible reason could be that under nitrogen deficiency the rest of available nitrogen is utilized for synthesis of enzymes and essential cell structures. Any carbon dioxide subsequently fixed is therefore converted into carbohydrate or lipid rather than protein [21]. As indicated from present results in (Figure 3), the addition of a carbon source caused marked increase in CDW, lipid content and lipid productivity for all tested species compared to the control. One interesting result, S. acuminatus, recorded the highest CDW under glycerol 0.3% (v/v) medium, while the same concentration inhibited the growth of C. aponicum. Moreover, a glycerol medium significantly enhanced lipid content and lipid productivity of C. sorokiniana and S. acuminatus to 5.2 and 2.8 folds respectively over control this finding is in accordance with [22], who reported that addition of 0.05 and 0.1 M of glycerol to Scenedesmus obliquus medium increased the biomass productivity by 6% and 5%, respectively during 12 days of incubation. [23] reported that the addition of glycerol in the culture medium of the red alga Gratelupia doryphora caused substantial increase of the total lipid and glycolipid content, while the amount of polar lipids remained constant. In contrast, addition of 0.3% glycerol (v/v) to C. aponicum medium inhibited growth this is due to the high osmotic pressure of that carbon source to this microorganism. This finding agreed also with [22], who found that culture treated with 0.2 M of glycerol showed inhibition of growth by 17% below the control. Although acetate medium significantly enhanced CDW for both C. sorokiniana and C. aponicum, their lipid content markedly decreased compared to control, this finding is in accordance with [24] who reported that biomass productivity and lipid content are inversely related. High lipid content microalgae cells generally show much slower growth, while those containing low lipid levels can have high growth rates [25,26]. In contrast molasses medium significantly enhanced lipid content and lipid productivity of C. aponicum to 2.8 folds over control after 12 days of incubation this results is agreed with [10], who reported that waste molasses hydrolysate alone may support rapid growth and high oil yield of Chlorella protothecoides. This is due to it containing both organic carbons and other nutrients. Molasses nutrients include vitamins, trace elements and many other kinds of ingredients; they consist mainly of 48% sugars [10,27].
6. Conclusion
A comparative study between three different microalgae chlorophyta (C.sorokiniana, S. acuminatus) and cyanobacterial species C. aponicum towards achieving high biomass, maximum lipid content and lipid productivity for biodiesel production. C. sorokiniana fulfils the major requirement for lipid production under OCM medium enriched with glycerol 0.3% (v/v). Lipid content of this strain could be further increased by decreasing nitrogen to −25%. The results have proved that the modification of the culture can tailor to the specific demands of highly productive microalgae to attain a consistently good yield of lipid. With further understanding on the cultivation of C. sorokiniana in photobioreactors, much greater productivity of algal lipid would be obtained. Moreover, the use of hydrolyzed molasses, a by-product of sugar refinery, as a cheap carbon source in mixotrophic cultures of C. aponicum strain stimulated both biomass and lipid content.
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