Food Microbiology (FM) | Bioactive Compounds or Metabolites: Function and Application
Microbiol. Biotechnol. Lett. 2024; 52(2): 114-121
https://doi.org/10.48022/mbl.2401.01001
Kuntal Sarma1,2, Preeti Chavak4, Doli1, Manju Sharma2, Narendra Kumar3, and Rama Kant1*
1Department of Botany, Chaudhary Charan Singh University (CCSU), Meerut 250004, India
2Department of Biotechnology, Amity University of Haryana, Manesar 122051, India
3Department of Botany, Guru Ghasidas Vishwavidyalaya, Bilaspur 495009, India
4Faculty of Biotechnology, Multanimal Modi College, Modinagar 201204, India
Correspondence to :
Rama Kant, ramakant.algae@gmail.com
The present communication deals with the standardization of suitable medium formulation along with anaerobically digested cow’s urine (ADCU) for growth of Spirulina subsalsa. Growth was evaluated on the basis of photosynthetic and non-photosynthetic pigment. The results obtained from the study indicated that, SSM-1 and SSM-2 media are suitable for maximum synthesis of chlorophyll-a and carotenoids. The obtained results also indicated that SSM-5 medium is suitable for maximum synthesis of accessory light harvesting pigments phycobiliprotein, total carbohydrate, total protein and total lipid in S. subsalsa. From the study it could be concluded that all the five media combinations (viz. SSM-1, SSM-2, SSM-3, SSM-4 and SSM-5) would be suitable for mass cultivation of S. subsalsa. But among them, SSM-5 medium combination could be the most suitable medium.
Keywords: Cow urine, chlorophyll-a, carotenoids, phycobiliprotein, carbohydrate, protein, lipid
Since the past few decades, Cyanobacteria (Blue-green Algae/Cyanoprokaryotes) are increasingly recognized as a prolific source of natural products and are well known for the production of a wide variety of bioactive compounds. Natural products from cyanobacteria were originally discovered through bioactivity-guided screening programs and revealed a truly fascinating variety of structures and inhibitory activities [1]. Recent reports on cyanobacteria also revealed that they have more than 300 nitrogen-containing secondary metabolites, represented by diverse structural types [2]. A majority of these secondary metabolites are biologically active and are products of either the non-ribosomal polypeptide (NRP) or the mixed polypeptide-NRP biosynthetic pathways [3]. The production of these low cost biologically active compounds could be used in food and pharmaceutical industries. Some marine forms of cyanobacteria are a source of potent neuro-toxins acting as an either blocker or activators [4].
The genus
The present work is focused on formulation and screening of low cost synthetic medium combinations along with anaerobically digested cow’s urine (ADCU) for the growth in biomass and synthesis of primary photosynthetic pigment like chlorophyll, accessory light harvesting pigment like phycobiliprotein, photoprotective pigment like carotenoids in
The experimental organism employed for the present study was isolated from logging waste water near Sobhapur, Meerut (U.P.), Bharat by repeated culturing and sub-culturing and deposited as
Experimental conditions were 28 ± 2℃ at light intensity of 138 μmol photons/m2/s1 for 14:10 hours light: dark regime. Under this condition
Table 1 . Chemical constituents of modified media specialized for
Chemicals | Amount (g/l) |
---|---|
CaCl2·2H2O | 0.036 |
Citric Acid | 0.006 |
NaNO3 | 1.5 |
FeSO4·7H2O | 0.006 |
EDTA (Na) | 0.001 |
MgSO4·7H2O | 0.075 |
K2HPO4 | 0.04 |
Na2CO3 | 0.02 |
NaHCO3 | 16 |
Solution A5 (Micronutrients) | 1.0 ml/l |
Table 2 . Chemical constituents of Solution A5 (Micronutrients).
Chemicals | Amount (g/l) |
---|---|
H3BO3 | 2.86 |
MnCl2·4 H2O | 1.81 |
ZnSO4·7H2O | 0.222 |
Na2MoO4·2H2O | 0.39 |
CuSO4·5H2O | 0.079 |
For the experiment fresh Cow’s urine was filtered and anaerobically digested for 21 days and four different synthetic media combinations SSM-2, SSM-3, SSM-4 and SSM-5 were formulated using 6.25%, 12.50%, 25% and 50% (ADCU) with 93.75%, 87.50%, 75% and 50% SSM-1 synthetic media respectively (Table 3). The culture flasks containing SSM-1 medium specialized for
Table 3 . Different combinations of synthetic medium for semi-continuous culturing of
Variants | Nutrient constituents of the Medium |
---|---|
SSM-1 | Modified nutrient medium specialized for |
SSM-2 | 6.25% ADCU + 93.75% SSM-1 |
SSM-3 | 12.50% ADCU + 87.5% SSM-1 |
SSM-4 | 25% ADCU + 75% SSM-1 |
SSM-5 | 50% ADCU + 50% SSM-1 |
The experiment was conducted in a completely randomized design in triplicates in 150 ml conical flasks (Borosil) containing 100 ml of SSM-1, SSM-2, SSM-3, SSM-4 and SSM-5 nutrient media. Exponentially growing
Quantitative estimation of chlorophyll pigment is essential for assessment of growth and photosynthetic rates in cyanobacteria.
Carotenoids include pigments like β-carotenes and xanthophylls soluble in polar solvents like acetone, exhibiting a characteristic absorption at 453 nm. The extraction of carotenoid pigment was done by the method followed by Jensen [9] in subdued light condition to avoid photoreaction and loss of pigments using microprocessor UV-VIS spectrophotometer against acetone blank.
Estimation of total proteins in the cells was done by the method followed by Lowry
Phycobilins namely phycocyanin (PC), phycoerythrin (PE), and allophycocyanin (APC) are water soluble pigments and extracted in phosphate buffer. Phycobilins or phycobiliproteins can be extracted by Bennett and Bogorad [11] method. The OD was measured at 562 nm, 615 nm and 652 nm in microprocessor UV-VIS spectrophotometer (Systronics 118) against phosphate buffer blank for C-phycocyanin, C-allophycocyanin and C-Phycoerythrin.
Carbohydrate is an important component of storage and structural material in cyanobacteria. The carbohydrate exists as free sugars and polysaccharides. Total carbohydrate content in the
Lipids are a diverse group of biological substances made up of primarily non-polar compounds (triglycerides, diglycerides, monoglycerides and sterols) and more polar compounds (free fatty acids, phospholipids and sphingolipids). They bind covalently to carbohydrates and proteins to form glycolipids and lipoproteins, respectively. Extraction of cyanobacterial lipid is an important key for biodiesel production based on microalgae. The Bligh and Dyer method [13] has been successfully applied for the determination of lipids from microalgae. This method is one of the widely practised methods for lipid extraction.
The data obtained were subjected to statistical analysis of variance (ANOVA) by using completely randomized design using the method followed by Armstrong and Hilton [14]. The statistical analysis was carried out in Microsoft Office Excel 2007. Each mean was calculated from six different values. Standard deviation and standard error were calculated against the values obtained.
Synthesis of
A gradual increase in the synthesis of photoprotective pigment carotenoid after semi-continuous supplement with five different media in the
Culture flasks semi-continuously supplemented with SSM-1 medium showed gradual increase in c-phycocyanin pigment till 20th day while after that a decline phase was observed. While a gradual enhance in the cphycocyanin content in other culture flasks semi-continuously supplemented with SSM-2, SSM-3, SSM-4 and SSM-5 synthetic media combinations was observed after 30 days. Maximum c-phycocyanin content was observed 0.017 μg/ml in the culture flasks supplemented with SSM-1 medium after 20 days while minimum c-phycocyanin content was observed 0.006 μg/ml when semicontinuously cultured under the influence of SSM-2 medium over a period of 30 days. A detailed result on the synthesis of c-phycocyanin pigment under the influence of SSM-1, SSM-2, SSM-3, SSM-4 and SSM-5 media is given in Fig. 1(C).
A drastic increase in the concentration of C-allophycocyanin in all the culture flasks was observed after 10 days while after that concentration of c-allophycocyanin declined in all the culture flasks supplemented with five different media combinations. Culture flasks semi-continuously supplemented with SSM-5 medium showed 0.097 μg/ml concentration of c-allophycocyanin after 10 days while minimum c-allophycocyanin content was observed 0.002 μg/ml when
The concentration of red light absorbing pigment cphycoerythrin increased in concentration in all the culture flasks supplemented with SSM-1, SSM-2, SSM-3, SSM-4 and SSM-5 media combinations. Maximum cphycoerythrin content was observed 0.112 μg/ml in the culture flask semi-continuously cultured under the influence of SSM-5 medium after 30 days. Minimum c-phycoerythrin content was observed 0.053 μg/ml in the culture flask supplemented semi-continuously with SSM-1 synthetic medium for 30 days. A detailed result on the synthesis of C-phycoerythrin pigment by
Among the various blue green alga,
Micro-algae
Cyanobacteria contain significant quantities of lipids and some of them are also rich in essential fatty acids such as linoleic and gamma linolenic acids. The lipid content in the cyanobacterial cells was determined under the influence of five different media over a period of 30 days harvesting semi-continuously every 10th day. A gradual increasing and then declining trend was observed in all the culture flasks supplemented semicontinuously with five different synthetic media. Maximum total lipid content was observed 0.007 mg/ml when
The blue green alga
A comparative study of
A new medium RM6 for mass production of
An investigation on growth pattern of
Lignite fly ash (LFA) is the by-product of thermal power station. The Blue Green Alga
The influence of an agricultural liquid organic fertilizer on growth and biomass composition of
Sarma
On the basis of the present investigation, it is concluded that SSM-1 medium combination along with ADCU could enhance the growth of
Authors are thankful to the Head, Department of Botany, Chaudhary Charan Singh University, Meerut, India for providing necessary facilities. Author (KS and MS) is thankful to the Director AIB, AIISH, Amity Institute of Biotechnology, Gurgaon for providing necessary facilities. Authors (RK and KS) thankfully acknowledge CCS University (Ref. No. DEV/URGS/2022-2023/24, Dated: 22/7/2022) and UP Govt (F.No. 70/2022/ 1543/Sattar-4-2022/001-70-4099-7-2022 Dated: 07- 07-2022) for providing financial support. Authors are also thankful to Prof. G. L. Tiwari, Ex. Head, Botany Department, University of Allahabad, Prayagraj for identification of all the strain.
The authors have no financial conflicts of interest to declare.
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