Analisis Pertumbuhan Khamir Endofit Buah Salak (Salacca edulis Reinw.) dengan Penambahan Zinc

Nur Kusmiyati, Ulfah Utami, Muhammad Riefki Pratama, Liliek Harianie

Abstract


Abstrak

Khamir endofit buah salak (Salacca edulis Reinw.) dengan kode YIS-3, YIS-4, dan YIS-7 dapat dimanfaatkan untuk fermentasi adonan roti. Kemampuan tersebut dapat ditingkatkan dengan penambahan sumber zinc pada media pertumbuhannya. Tujuan penelitian ini untuk menganalisis pertumbuhan khamir endofit buah salak dengan penambahan zinc dan kualitas roti hasil fermentasi. Metode yang digunakan meliputi peremajaan isolat khamir, penambahan nutrisi pada media pertumbuhan, analisis biomassa khamir, jumlah sel, volume adonan, dan organoleptik. Hasil penelitian pada parameter pertumbuhan menunjukkan bahwa perlakuan dengan penambahan zinc 0,1 g/L menghasilkan biomassa dan jumlah sel lebih tinggi dibandingkan perlakuan kontrol. Biomassa tertinggi dihasilkan oleh YIS-4 yakni 4,13 g/300 mL, sedangkan jumlah sel tertinggi dihasilkan oleh YIS-3 yakni 27,84 x 106 sel/mL. Pada persentase pengembangan menunjukkan bahwa isolat khamir dengan perlakuan zinc 0,1 g/L membutuhkan waktu lebih lama untuk mencapai pengembangan tertinggi, namun volume roti setelah pemanggangan menunjukkan hasil yang lebih baik dibanding perlakuan kontrol. Isolat YIS-4 dengan perlakuan zinc 0,1 g/L menghasilkan volume roti tertinggi (949,54 cm3). Berdasarkan analisis organoleptik dengan parameter warna, aroma, rasa dan tekstur menunjukkan bahwa semua panelis lebih menyukai roti hasil fermentasi isolat YIS-4 dengan perlakuan zinc 0,1 g/L.

Abstract

The endophytic yeast of salak fruit (Salacca edulis Reinw.) with codes YIS-3, YIS-4, and YIS-7 can be used for bread dough fermentation. This ability can be increased by adding a zinc source to the growth medium. The purpose of this study was to analyze the growth of the endophytic yeast of salak fruit with the addition of zinc and the quality of fermented bread. The methods used include rejuvenation of yeast isolates, addition of nutrients to growth media, analysis of yeast biomass, cell count, dough volume and organoleptic. The results of research on growth parameters showed that treatment with the addition of zinc 0.1 g/L resulted in higher biomass and cell count than the control treatment. The highest biomass was produced by YIS-4 which was 4.13 g/300 mL, while the highest number of cells was produced by YIS-3 which was 27.84 x 106 cells/mL. The swelling percentage showed that yeast isolates treated with 0.1 g/L zinc took longer to reach the highest swelling, but the volume of bread after baking showed better results than the control treatment. YIS-4 isolate treated with 0.1 g/L zinc produced the highest bread volume (949.54 cm3). Based on organoleptic analysis with parameters of color, aroma, taste and texture, it showed that all panelists preferred bread fermented YIS-4 isolate with 0.1 g/L zinc treatment.


Keywords


Khamir; Roti; Zinc; Bread; Yeast;

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References


Akbar, G. P., Kusdiyantini, E., & Wijanarka, W. (2019). Isolasi dan karakterisasi secara morfologi dan biokimia khamir dari limbah kulit nanas madu (Ananas comosus L.) untuk produksi bioetanol. Berkala Bioteknologi, 2(2), 1-11.

Atanasova, M., Yordanova, G., Nenkova, R., Ivanov, Y., Godjevargova, T., & Dinev, D. (2019). Brewing yeast viability measured using a novel fluorescent dye and image cytometer. Biotechnology and Biotechnological Equipment, 33(1), 548-558.

Azad, S. K., Shariatmadari, F., & Torshizi, M. A. K. (2014). Production of zinc-enriched biomass of Saccharomyces cerevisiae. Journal Element, 313-326.

Choiriyah, N. A., & Dewi, I. C. (2020). Daya terima roti tawar mocaf dan ubi jalar pada santriwati pesantren x. Media Pertanian, 5(1).

Heitmann, M., Zannini, E., Axel, C., & Arendt, E. (2017). Correlation of flavor profile to sensory analysis of bread produced with different Saccharomyces cerevisiae originating from the baking and beverage industry. Cereal Chemistry, 94(4), 746-751.

Karki, T. B., Timilsina, P. M., Yadav, A., Pandey, G. R., Joshi, Y., Bhujel, S., ... & Neupane, K. (2017). Selection and characterization of potential baker's yeast from indigenous resources of Nepal. Biotechnology research international, 2017.

Kim, D. H., Jang, K. A., & Lee, S. J. (2020). Prediction method of co2 production from electrical resistance of bread dough measured with a simple electrical multimeter in fermentation. Food Science and Biotechnology, 29(2), 235-241.

Lahue, C., Madden, A. A., Dunn, R. R., & Heil, C. S. (2020). History and domestication of Saccharomyces cerevisiae in bread baking. Frontiers in Genetics, 11.

Mahardika, G. R., & Pratikno, H. (2018). Analisis ketahanan mikroalga pada material baja ah 36 dengan menggunakan metode impressed current anti fouling (ICAF). Jurnal Teknik ITS, 7(2), G145-G149.

Maicas, S. (2020). The role of yeasts in fermentation processes. Microorganisms, 8(1142), 1-8. doi: 10.3390/microorganisms8081142.

Maryam, B. M., Mohammed, S. S. D., & Ayodeji, O. A. (2017). Screening of fermentative potency of yeast isolats from indigenous sources for dough leavening. International Journal of Microbiology and Biotechnology, 2(1), 12.

Mildner-Szkudlarz, S., Siger, A., Szwengiel, A., Przygoński, K., Wojtowicz, E., & Zawirska-Wojtasiak, R. (2017). Phenolic compounds reduce formation of nε-(carboxymethyl) lysine and pyrazines formed by maillard reactions in a model bread system. Food chemistry, 231, 175-184.

Ouedraogo, N., Savadogo, A., Somda, M. K., Tapsoba, F., Zongo, C., & Traore, A. S. (2017). Effect of mineral salts and nitrogen source on yeast (Candida utilis NOY1) biomass production using tubers wastes. African Journal of Biotechnology, 16(8), 359-365.

Pérez-Torrado, R., Gamero, E., Gómez-Pastor, R., Garre, E., Aranda, A., & Matallana, E. (2015). Yeast biomass, an optimised product with myriad applications in the food industry. Trends in Food Science & Technology, 46(2), 167-175.

Purlis, E. (2010). Browning development in bakery products–a review. Journal of Food Engineering, 99(3), 239-249.

Pusuma, D. A., Praptiningsih, Y., & Choiron, M. (2018). Karakteristik roti tawar kaya serat yang disubstitusi menggunakan tepung ampas kelapa. Jurnal Agroteknologi, 12(01), 29-42.

Qurnaini, N. R., Nasrullah, N., & Fauziyah, A. (2021). Pengaruh substitusi biji jali (Coix lacryma-jobi L.) terhadap kadar lemak, serat, fenol dan sifat organoleptik tempe. Jurnal Pangan dan Gizi, 11(01).

Saepudin, L., Setiawan, Y., & Sari, P. D. (2017). Pengaruh perbandingan substitusi tepung sukun dan tepung terigu dalam pembuatan roti manis. AGROSCIENCE, 7(1), 227-243.

Sitepu, K. M. (2019). Penentuan konsentrasi ragi pada pembuatan roti (determining of yeast concentration on bread making). Jurnal Penelitian dan Pengembangan Agrokompleks, 71-77.

Starowicz, M., & Zieliński, H. (2019). How maillard reaction influences sensorial properties (color, flavor and texture) of food products?. Food Reviews International, 35(8), 707-725.

Walker, G. M., & Stewart, G. G. (2016). Saccharomyces cerevisiae in the production of fermented beverages. Beverages, 2(30).

Wan, C., Zhang, M., Fang, Q., Xiong, L., Zhao, X., Hasunuma, T., … Kondo, A. (2014). The impact of zinc sulphate addition on the dynamic metabolic profiling of Saccharomyces cerevisiae subjected to long term acetic acid stress treatment and identification of key metabolites involved the antioxidant effect of zinc. Royal Society of Chemistry.

Watanabe, M., Uchida, N., Fujita, K., Yoshino, T., & Sakaguchi, T. (2016). Bread and effervescent beverage productions with local microbes for the local revitalization. International Journal on Advanced Science, Engineering and Information Technology, 6(3), 381-384.

Zahroh, N. (2022). Analisis senyawa volatil pada roti hasil fermentasi oleh khamir endofit buah salak pondoh (Salacca edulis Reinw.) beserta identifikasi molekuler. Universitas Islam Negeri Maulana Malik Ibrahim Malang, Jawa Timur, Indonesia.

Zhao, X. Q., Xue, C., Ge, X. M., Yuan, W. J., Wang, J. Y., & Bai, F. W. (2009). Impact of zinc supplementation on the improvement of ethanol tolerance and yield of self-flocculating yeast in continuous ethanol fermentation. Journal of Biotechnology, 139(1), 55-60.

Zhao, X. Q., & Bai, F. W. (2012). Zinc and yeast stress tolerance: Micronutrient plays a big role. Journal of Biotechnology, 158(4), 176-183.

Zhen, S., Deng, X., Xu, X., Liu, N., Zhu, D., Wang, Z., & Yan, Y. (2020). Effect of high-nitrogen fertilizer on gliadin and glutenin subproteomes during kernel development in wheat (Triticum aestivum L.). Crop Journal, 8(1), 38-52.

Zohri, A. A., Fadel, M., Hmad, M., & El-sharkawey, H. F. (2017). Effect of nitrogen sources and vitamins addition on baker’s yeast fermentation activity. Egyptian Sugar Journal, 9, 57-66.




DOI: https://doi.org/10.15408/kauniyah.v17i2.31921 Abstract - 0 PDF - 0

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