The study explores the impact of different organic carbon sources and agricultural fertilizers on the growth and metabolite production of marine benthic diatom Cylindrotheca sp. The results revealed that the highest cell density was recorded in the cultures supplied with urea (1 g L−1), which was 1.9% more than the control. The protein content was increased (1.75%) in the cultures treated with different C and N sources compared to the control. The total chlorophyll and carotenoid content was highest in the cultures with 1.5 g L−1 sucrose (25 ± 0.33 mg g−1) and 0.5 g L−1 glucose (10.25 ± 0.13 mg g−1), respectively. Further, the fatty acid profile reveals that total MUFA (monounsaturated fatty acids) was maximum in sucrose at 1.5 g L−1 (45.63%) followed by control (31.25%). C22:5 (Docosapentaenoic acid) was found to be maximum in sucrose 1.5 g L−1 (6.98%) and eicosapentaenoic acid (EPA) was maximum in glycerol 1.5 g L−1 (14.37%). Thus, based on the results, it can be inferred that since different nutrients have varying effects on diatom growth and biomolecule production, this study can aid in selecting a suitable upstream approach based on the desired downstream application. The study provides pioneering evidence on how specific nutrient combinations (e.g., urea, sucrose, glucose) optimize the production of biomolecules such as MUFA and PUFA (polyunsaturated fatty acids), which have high value in nutraceutical and pharmaceutical industries.
GérinSDelhezTCoratoA, et al.A novel culture medium for freshwater diatoms promotes efficient photoautotrophic batch production of biomass, fucoxanthin, and eicosapentaenoic acid. J Appl Phycol2020; 32: 1581–1596.
2.
VillanovaVSpeteaC. Mixotrophy in diatoms: molecular mechanism and industrial potential. Physiol Plant2021; 173: 603–611.
3.
ZhengYQuinnAHSriramG. Experimental evidence and isotopomer analysis of mixotrophic glucose metabolism in the marine diatom Phaeodactylum tricornutum. Microb Cell Fact2013; 12: 109.
4.
ArmstrongERogersonALeftleyJW. Utilisation of seaweed carbon by three surface-associated heterotrophic protists, Stereomyxa ramosa, Nitzschia alba and Labyrinthula sp. Aquat Microb Ecol2000; 21: 49–57.
5.
SumanKKiranTDeviUK,et al.Culture medium optimization and lipid profiling of Cylindrotheca, a lipid- and polyunsaturated fatty acid-rich pennate diatom and potential source of eicosapentaenoic acid. Bot Mar2012; 55: 289–299.
6.
MarellaTKBhattacharjyaRTiwariA. Impact of organic carbon acquisition on growth and functional biomolecule production in diatoms. Microb Cell Fact2021; 20: 135.
7.
FuWWichukKBrynjólfssonS. Developing diatoms for value-added products: challenges and opportunities. New Biotechnol2015; 32: 547–551.
8.
WangHZhangYChenL, et al.Combined production of fucoxanthin and EPA from two diatom strains Phaeodactylum tricornutum and Cylindrotheca fusiformis cultures. Bioprocess. Biosyst Eng2018; 41: 1061–1071.
9.
ZhangWWangFGaoB, et al.An integrated biorefinery process: stepwise extraction of fucoxanthin, eicosapentaenoic acid and chrysolaminarin from the same Phaeodactylum tricornutum biomass. Algal Res2018; 32: 193–200.
10.
LewinJCLewinRA. Auxotrophy and heterotrophy in marine littoral diatoms. Can J Microbiol1960; 6: 127–134.
11.
TuchmanNCSchollettMARierST,et al.Differential heterotrophic utilization of organic compounds by diatoms and bacteria under light and dark conditions. Hydrobiologia2006; 561: 167–177.
12.
NeilsonAHLewinRA. The uptake and utilization of organic carbon by algae: an essay in comparative biochemistry. Phycologia1974; 13: 227–264.
13.
SinghPKSaxenaATyagiR, et al.Biomass valorization of agriculture wastewater grown freshwater diatom Nitzschia sp. for metabolites, antibacterial activity, and biofertilizer. Bioresour Technol2023; 377: 128976.
14.
GuillardRRLRytherJH. Studies of marine planktonic diatoms. I. Cyclotella nana Hustedt and Detonula confervacea (cleve) gran. Can J Microbiol1962; 8: 229–239.
15.
WangXWLiangJR, et al.Biomass, total lipid production, and fatty acid composition of the marine diatom Chaetoceros muelleri in response to different CO2 levels. Bioresour Technol2014; 161: 124–130.
16.
BradfordMM. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem1976; 72: 248–254.
17.
KoehlerLH. Differentiation of carbohydrates by anthrone reaction rate and colour intensity. Anal Chem1952; 24: 1576–1579.
18.
SudhakarMPAnanthalakshmiJSNairBB. Extraction, purification, and study on antioxidant properties of fucoxanthin from brown seaweeds. J Chem Pharm2013; 5: 169–175.
19.
SafafarHWagenenJVMøllerP,et al.Carotenoids, phenolic compounds, and tocopherols contribute to the antioxidative properties of some microalgae species grown on industrial wastewater. Mar Drugs2015; 13: 7339–7356.
20.
BhattacharjyaRMarellaTKTiwariA, et al.Bioprospecting of marine diatoms Thalassiosira, Skeletonema and Chaetoceros for lipids and other value-added products. Bioresour Technol2020; 318: 124073.
21.
GranumEMyklestadSM. A simple combined method for determination of β−1,3-glucan and cell wall polysaccharides in diatoms. Sci Technol2002; 477: 155–161.
22.
BlighEGDyerWJ. A rapid method of total lipid extraction and purification. Can J Biochem Physiol1959; 37: 911–917.
23.
MarellaTKParineNRTiwariA. Potential of diatom consortium developed by nutrient enrichment for biodiesel production and simultaneous nutrient removal from wastewater. Saudi J Biol Sci2018; 25: 704–709.
24.
DuboisMGillesKAHamiltonJK, et al.Colorimetric method for determination of sugars and related substances. Anal Chem1956; 28: 350–356.
25.
MurisonVH´eraultJSchoefsB, et al.Bioinformatics based screening approach for the identification and characterization of lipolytic enzymes from the marine diatom Phaeodactylum tricornutum. Mar Drugs2023b; 21: 125.
26.
SaxenaAMishraBSindhuR, et al.Nutrient acclimation in benthic diatoms with adaptive laboratory evolution. Bioresour Technol2022; 351: 126955.
27.
SuYYiZBjörnsdóttirSH, et al.Adaptive Laboratory Evolution for Enhanced Carotenoid Production in Microalgae. In: BarreiroCBarredoJL (eds) Microbial Carotenoids. Methods Mol Bio 2018. New York, NY: Humana Press, 1852, pp.117–126.
28.
VillanovaVSpeteaC. Mixotrophy in diatoms: molecular mechanism and industrial potential. Physiol Plant2021; 173: 603–611.
29.
BhattacharjyaRTyagiRRastogiS, et al.Response of varying combined nutrients on biomass and biochemical composition of marine diatoms Chaetoceros gracilis and Thalassiosira weissflogii. Bioresour Technol2024; 394: 130274.
30.
LiuXDuanSLiA, et al.Effects of organic carbon sources on growth, photosynthesis, and respiration of Phaeodactylum tricornutum. J Appl Phycol2008; 21: 239–246.
31.
RamakrishnaARavishankarGA. Influence of abiotic stress signals on secondary metabolites in plants. Plant Signal Behav2011; 6: 1720–1731.
32.
AnsariFASinghPGuldheA,et al.Microalgal cultivation using aquaculture wastewater:integrated biomass generation and nutrient remediation. Algal Res2017; 21: 169–177.
33.
WillisAChiovittiADugdaleTM,et al.Characterization of the extracellular matrix of Phaeodactylum tricornutum (Bacillariophyceae): structure, composition, and adhesive characteristics. J Phycol2013; 49: 937–949.
34.
SayanovaOMimouniVUlmannL, et al.Modulation of lipid biosynthesis by stress in diatoms. Philos Trans R Soc Lond B Biol Sci2017; 372: 20160407.
35.
WangSSirbuDThomsenL, et al.Comparative lipidomic studies of Scenedesmus sp. (Chlorophyceae) and Cylindrotheca Closterium (Bacillariophyceae) reveal their differences in lipid production under nitrogen starvation. J Phycol2019; 55: 1246–1257.
36.
TyagiRSinghPKSaxenaA, et al. Exploring the nutraceutical potential of high-altitude freshwater diatom Nitzschia sp. in batch culture. Syst Microbiol and Biomanuf2024; 4: 1262–1272.
37.
SinghPKMarellaTKBhattacharjyaR, et al.Marine diatom algae cultivation in simulated dairy wastewater and biomass valorization. Environ Sci Pollut Res2024; 31: 57466–57477.
38.
SinghPKParikhHSaxenaA, et al.Managing municipal wastewater remediation employing alginate-immobilized marine diatoms and silver nanoparticles. Energy & Environ2024; 35: 1049–1063.
39.
NurMMA. Co-production of fucoxanthin and lipid from Indonesian diatom and green algae growing on palm oil mill effluent under mixotrophic conditions. Biocatal Agric Biotechnol2021; 38: 102228.
40.
NurMMAMuizelaarWBoelenP,et al.Environmental and nutrient conditions influence fucoxanthin productivity of the marine diatom Phaeodactylum tricornutum grown on palm oil mill effluent. J Appl Phycol2019; 31: 111–122.
