Iranian Food Science and Technology Research Journal

Current Issue

By Issue

By Author

Author Index

Keyword Index

About Journal

Aims and Scope

Publication Ethics

Indexing and Abstracting

FAQ

Peer Review Process

Journal Metrics

Manuscript Structure

Download guide files

Article Submission Checklist

Reviewer Guide

Journal Reviewers List

Using Microwave Pretreatment in the Enzymatic Hydrolysis of Pumpkin Seed Protein (Cucurbita maxima L.) by Alcalase and Investigating Its Antioxidant Properties

Document Type : Full Research Paper

Authors

1 Department of Food Science and Technology, Faculty of Food Industry, Gorgan University of Agricultural Sciences and Natural Resources, Gorgan, Iran

2 Cancer Research Center, Golestan University of Medical Sciences, Gorgan, Iran

10.22067/ifstrj.2023.82861.1264

Abstract

Introduction
Seeds and nuts have received increasing attention due to their nutritional value and the high therapeutic properties of their bioactive compounds. Most of the seeds are used as nuts, and some of them are considered agricultural waste. Pumpkin seeds have a high content of protein (30–40% in terms of dry matter). Proteins are among the vital health-giving components that provide nitrogen, essential amino acids and energy necessary for normal cells. Pumpkin seeds are a good source of amino acids such as valine, histidine, isoleucine, leucine, threonine and methionine. Protein hydrolysate is a mixture of peptides and amino acids that can show antioxidant, antimicrobial, anticancer, antidiabetic and antihypertensive properties. During hydrolysis, proteins are broken into small peptides and amino acids. Since enzymatic hydrolysis is performed in relatively mild conditions and no amino acid damage occurs, this type of hydrolysis is preferred over acid and alkaline hydrolysis. Hydrolysates obtained from pumpkin seed protein have bioactive properties, especially antioxidant activity. Pretreatment of proteins before enzymatic hydrolysis acts to improve the release of bioactive peptides from different proteins. Pretreatment can facilitate the unfolding the structure of proteins and thus increase the access of enzymes to peptide bonds. The main properties of microwaves usually show three characteristics: penetration, reflection and absorption. Microwave assisted enzymatic hydrolysis can shorten the time  and improve the speed of the reaction. The purpose of this research was to investigate the antioxidant activity of pumpkin seed protein hydrolysates (Cucurbita maxima L.) by alcalase enzyme in two conditions: without pretreatment and using microwave pretreatment.
 
Material and Methods
In this study, Pumpkin (Cucurbita maxima L.) was purchased from the local market of Astane Ashrafieh in Gilan province. The seeds were scooped manuallyand then dried in an oven at 50°C for 72 hours. After the production of protein concentrate from pumpkin seeds, the chemical properties of the concentrate, such as the amount of fat, protein, ash and moisture, were measured. The isolated pumpkin seed solution was exposed to microwave energy with a power of 450-900 watts for 30–90 seconds and was used as a substrate solution in enzymatic hydrolysis experiments. It should be noted that after measuring the total antioxidantactivityr for different powers and times of microwave pretreatment, the power of 600 watts for 60 seconds was selected  and applied before enzymatic hydrolysis. Enzymatic hydrolysis was done by alcalase enzyme with a concentration of 0.5 to 2.5% compared to the protein substrate during 20 to 190 minutes, and the optimum temperature and pH of alcalase were determined in order to produce hydrolysates with antioxidant activity. Antioxidant activity was measured by using DPPH free radical inhibition, total antioxidant activity and iron chelation activity methods.
 
Result and Discussion
Bioactive peptides produced by the enzymatic hydrolysis of proteins have significant antioxidant properties. Pumpkin seeds can be used as a rich source of nutrients and bioactive compounds in various food industries. The results showed that the maximum amount of antioxidant activity without pre-treatment was achieved in 165 minutes with a 2.2% ratio of E/S by using DPPH free radical scavenging activity (40.5%), total antioxidant power (0.79), and iron chelation activity (96.2%) methods. By using microwave pre-treatment, the maximum amount of antioxidant activity was achieved in a shorter time and with less enzyme (105 minutes and E/S ratio 1.5%) using DPPH free radical scavenging (52%), total antioxidant power (0.711), and iron chelation activity (93%). Therefore, it can be concluded that using microwave assisted enzymatic hydrolysis , in addition to achieving hydrolysates with proper antioxidant activity, is a suitable method to save time and reduce enzyme concentrations used in enzymatic hydrolysis.

Keywords

Main Subjects

©2023 The author(s). This is an open access article distributed under Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source.
References
  1. Alvand, M., Sadeghi Mahoonak, A., Ghorbani, M., Shahiri Tabarestani, H., & Kaveh, S. (2022). Comparison of the antioxidant properties of hydrolyzed Turkmen melon seed protein by Pancreatin and Alcalase. Food Engineering Research, 21(2), 75-90. https://doi.org/10.22092/fooder.2023.354314.1303
  2. Batista, I., Ramos, C., Coutinho, J., Bandarra, N., & Nunes, M. (2010). Characterization of protein hydrolysates and lipids obtained from black scabbardfish (Aphanopus carbo) by-products and antioxidative activity of the hydrolysates produced. Process Biochemistry, 45(1), 18-24.
  3. da Rosa, G.S., Vanga, S.K., Gariepy, Y., & Raghavan, V. (2019). Comparison of microwave, ultrasonic and conventional techniques for extraction of bioactive compounds from olive leaves (Olea europaea). Innovative Food Science & Emerging Technologies, 58, 102234. https://doi.org/10.1016/j.ifset.2019.102234
  4. Devi, N.M., Prasad, R., & Palmei, G. (2018). Physico-chemical characterisation of pumpkin seeds. International Journal of Chemical Studies, 6(5), 828-831.
  5. Dong, C., Li, F., Wang, L., Ma, X., Xu, J., & Kong, L. (2015). Microwave pretreatment of sunflower meal protein preparation of antioxidant peptides. Science Technology Food Industry, 36, 308-311.
  6. Drotningsvik, A., Mjøs, S.A., Pampanin, D.M., Slizyte, R., Carvajal, A., Remman, T., Høgøy, I., & Gudbrandsen, O.A. (2016). Dietary fish protein hydrolysates containing bioactive motifs affect serum and adipose tissue fatty acid compositions, serum lipids, postprandial glucose regulation and growth in obese Zucker fa/fa rats. British Journal of Nutrition, 116(8), 1336-1345. https://doi.org/10.1017/S0007114516003548
  7. Fan, X., Guo, H., Teng, C., Zhang, B., Blecker, C., & Ren, G. (2022). Anti-colon cancer activity of novel peptides isolated from in vitro digestion of quinoa protein in Caco-2 cells. Foods, 11(2), 194.
  8. Gazikalović, I., Mijalković, J., Šekuljica, N., Jakovetić Tanasković, S., Đukić Vuković, A., Mojović, L., & Knežević-Jugović, Z. (2021). Synergistic effect of enzyme hydrolysis and microwave reactor pretreatment as an efficient procedure for gluten content reduction. Foods, 10(9), 2214.
  9. Gohi, B.F.C.A., Du, J., Zeng, H.-Y., Cao, X.-J., & Zou, K.M. (2019). Microwave pretreatment and enzymolysis optimization of the Lotus seed protein. Bioengineering, 6(2), 28.
  10. Han, R., Álvarez, A.J.H., Maycock, J., Murray, B.S., & Boesch, C. (2021). Comparison of alcalase-and pepsin-treated oilseed protein hydrolysates–experimental validation of predicted antioxidant, antihypertensive and antidiabetic properties. Current Research in Food Science, 4, 141-149.
  11. Horax, R., Vallecios, M.S., Hettiarachchy, N., Osorio, L.F., & Chen, P. (2017). Solubility, functional properties, ACE‐I inhibitory and DPPH scavenging activities of Alcalase hydrolysed soy protein hydrolysates. International Journal of Food Science & Technology, 52(1), 196-204. https://doi.org/10.1111/ijfs.13267
  12. Horwitz, W., & Latimer, G. (2000). Association of official analytical chemists. Gaithersburg, MD, USA.
  13. Kanbargi, K.D., Sonawane, S.K., & Arya, S.S. (2017). Encapsulation characteristics of protein hydrolysate extracted from Ziziphus jujube International Journal of Food Properties, 20(12), 3215-3224.
  14. Kaveh, S., Sadeghi, M.A., Ghorbani, M., Jafari, M., & Sarabandi, K. (2019). Optimization of factors affecting the antioxidant activity of fenugreek seed's protein hydrolysate by response surface methodology. Iranian Journal of Nutrition Sciences & Food Technology, 14(1).
  15. Li, D., Wang, J., Wu, X., Feng, C., & Li, X. (2013). Ultraviolet-assisted synthesis of hourglass-like ZnO microstructure through an ultrasonic and microwave combined technology. Ultrasonics Sonochemistry, 20(1), 133-136. https://doi.org/10.1016/j.ultsonch.2012.05.017
  16. Lu, D., Peng, M., Yu, M., Jiang, B., Wu, H., & Chen, J. (2021). Effect of enzymatic hydrolysis on the zinc binding capacity and in vitro gastrointestinal stability of peptides derived from pumpkin (Cucurbita pepo) seeds. Frontiers in Nutrition, 8, 647782.
  17. Maqsoudloua, S., Mahoonak, R., & Mohebodini, A. (2018). Evaluation of the antioxidant properties Hydrolyzed protein of bee pollen. Food Science and Technology, 14(12), 227-240.
  18. Mazloomi-Kiyapey, S.N., Sadeghi-Mahoonak, A., Ranjbar-Nedamani, E., & Nourmohammadi, E. (2019). Production of antioxidant peptides through hydrolysis of medicinal pumpkin seed protein using pepsin enzyme and the evaluation of their functional and nutritional properties. Arya Atherosclerosis, 15(5), 218.
  19. Meshginfar, N., Sadeghi, M.A., Ziaiifar, A., Ghorbani, M., & Kashaninejad, M. (2014). Optimization of the production of protein hydrolysates from meat industry by products by response surface methodology. Journal of Food Research (University of Tabriz).
  20. Nguyen, E., Jones, O., Kim, Y.H.B., San Martin-Gonzalez, F., & Liceaga, A.M. (2017). Impact of microwave-assisted enzymatic hydrolysis on functional and antioxidant properties of rainbow trout Oncorhynchus mykiss by-products. Fisheries Science, 83, 317-331.
  21. Nkosi, C.Z. (2007). Effect of pumpkin seed (Cucurbita pepo) protein isolate on the antioxidant enzymes in ccl4-induced liver injury in low-protein fed rats.
  22. Nnamezie, A.A., Famuwagun, A.A., & Gbadamosi, S.O. (2021). Characterization of okra seed flours, protein concentrate, protein isolate and enzymatic hydrolysates. Food Production, Processing and Nutrition, 3, 1-14.
  23. Nourmohammadi, E., Sadeghi, M.A., Ghorbani, M., Alami, M., & Sadeghi, M. (2016). Identification of the optimum conditions to anti-oxidative peptides production through the enzymatic hydrolysis of pumpkin oil cake protein by pepsin.
  24. Ovissipour, M., Abedian, A., Motamedzadegan, A., Rasco, B., Safari, R., & Shahiri, H. (2009). The effect of enzymatic hydrolysis time and temperature on the properties of protein hydrolysates from Persian sturgeon (Acipenser persicus) viscera. Food Chemistry, 115(1), 238-242.
  25. Prieto, P., Pineda, M., & Aguilar, M. (1999). Spectrophotometric quantitation of antioxidant capacity through the formation of a phosphomolybdenum complex: specific application to the determination of vitamin E. Analytical Biochemistry, 269(2), 337-341.
  26. Rezig, L., Chibani, F., Chouaibi, M., Dalgalarrondo, M.L., Hessini, K., Guéguen, J., & Hamdi, S. (2013). Pumpkin (Cucurbita maxima) seed proteins: sequential extraction processing and fraction characterization. Journal of Agricultural and Food Chemistry, 61(32), 7715-7721. https://doi.org/10.1021/jf402323u
  27. Rezig, L., Chouaibi, M., Msaada, K., & Hamdi, S. (2012). Chemical composition and profile characterisation of pumpkin (Cucurbita maxima) seed oil. Industrial Crops and Products, 37(1), 82-87.
  28. Samaranayaka, A.G., & Li-Chan, E.C. (2011). Food-derived peptidic antioxidants: A review of their production, assessment, and potential applications. Journal of Functional Foods, 3(4), 229-254. https://doi.org/10.1016/j.jff.2011.05.006
  29. Sarkar, S.K., Hossain, M.T., Uddin, M.B., & Absar, N. (2007). Purification, characterization and physico-chemical properties of three galactose-specific lectins from pumpkin (Cucurbita maxima) seed kernels. Journal of the Chinese Chemical Society, 54(6), 1433-1442.
  30. Shaban Pour, B., Kord Jazi, M., Nazari, K., & Esmaeeli Khariki, M. (2017). Effect of enzymatic hydrolysis time, temperature and enzyme to substrate ratio on antioxidant properties of prawn bioactive peptides. Journal of Food Science and Technology (Iran), 14(62), 45-31.
  31. Shandilya, U., & Sharma, A. (2017). Functional foods and their benefits: an overview. Journal Nutrition Health Food Engineering, 7(4), 353-356.
  32. Sitohy, M.Z., Desoky, E.S.M., Osman, A., & Rady, M.M. (2020). Pumpkin seed protein hydrolysate treatment alleviates salt stress effects on Phaseolus vulgaris by elevating antioxidant capacity and recovering ion homeostasis. Scientia Horticulturae, 271, 109495. https://doi.org/10.1016/j.scienta.2020.109495
  33. Taha, F.S., Mohamed, S.S., Wagdy, S.M., & Mohamed, G.F. (2013). Antioxidant and antimicrobial activities of enzymatic hydrolysis products from sunflower protein isolate. World Applied Science Journal, 21(5), 651-658.
  34. Uluko, H., Zhang, S., Liu, L., Tsakama, M., Lu, J., & Lv, J. (2015). Effects of thermal, microwave, and ultrasound pretreatments on antioxidative capacity of enzymatic milk protein concentrate hydrolysates. Journal of Functional Foods, 18, 1138-1146.
  35. Villanueva-Lazo, A., Paz, S. M.-d. l., Rodriguez-Martin, N. M., Millan, F., Carrera, C., Pedroche, J. J., & Millan-Linares, M. d. C. (2021). Antihypertensive and antioxidant activity of Chia protein techno-functional extensive hydrolysates. Foods, 10(10), 2297.
  36. Wang, S., Su, G., Zhang, X., Song, G., Zhang, L., Zheng, L., & Zhao, M. (2021). Characterization and exploration of potential neuroprotective peptides in walnut (Juglans regia) protein hydrolysate against cholinergic system damage and oxidative stress in scopolamine-induced cognitive and memory impairment mice and zebrafish. Journal of Agricultural and Food Chemistry, 69(9), 2773-2783. https://doi.org/10.1021/acs.jafc.0c07798
  37. Yang, C., Wang, B., Wang, J., Xia, S., & Wu, Y. (2019). Effect of pyrogallic acid (1, 2, 3-benzenetriol) polyphenol-protein covalent conjugation reaction degree on structure and antioxidant properties of pumpkin (Cucurbita) seed protein isolate. Lwt, 109, 443-449. https://doi.org/10.1016/j.lwt.2019.04.034
  38. Yang, X., Ren, X., & Ma, H. (2022). Effect of microwave pretreatment on the antioxidant activity and stability of enzymatic products from milk protein. Foods 2022, 11, 1759. In: s Note: MDPI stays neutral with regard to jurisdictional claims in published.
  39. Zakeri, K., Ghorbani, M., Mahoonak, A.S., Moayedi, A., & Maghsoudlou, Y. (2019). Determination of optimum conditions for the production of peptides with antioxidant and nitric-oxide inhibition properties from protein hydrolysis of pumpkin seed meals using pepsin enzyme. Iranian Journal of Nutrition Sciences & Food Technology, 14(3).
  40. Zhang, X., Li, H., Wang, L., Zhang, S., Wang, F., Lin, H., Gao, S., Li, X., & Liu, K. (2021). Anti‐inflammatory peptides and metabolomics‐driven biomarkers discovery from sea cucumber protein hydrolysates. Journal of Food Science, 86(8), 3540-3549. https://doi.org/10.1111/1750-3841.15834
  41. Zhu, L., Chen, J., Tang, X., & Xiong, Y.L. (2008). Reducing, radical scavenging, and chelation properties of in vitro digests of alcalase-treated zein hydrolysate. Journal of Agricultural and Food Chemistry, 56(8), 2714-2721.
  42. Salo-Viiiinhen, P.P., & Koivistoinen, P.E. (1996). Determination of protein in foods: comparison of net protein and crude protein (Nx 6.25) values. Food Chembtry, 57(1), 27-31.

 

Send comment about this article
CAPTCHA Image
Iranian Food Science and Technology Research Journal
Volume 20, Issue 2 - Serial Number 86
May and June 2024
Pages 295-308
Files
History
  • Receive Date: 12 June 2023
  • Revise Date: 06 December 2023
  • Accept Date: 09 December 2023
  • First Publish Date: 09 December 2023
Share
How to cite
Statistics