PROFIL PROTEIN SUSU DAN PRODUK OLAHANNYA
(1) Jurusan Biologi, Fakultas MIPA, Universitas Negeri Semarang, Indonesia
(2) SD Negeri 1 Suka Mulya, Kecamatan Lemong, Pesisir Barat, Lampung
Abstract
Penelitian ini bertujuan untuk menganalisis kadar protein dan profil protein pada beberapa susu (susu kedelai, susu kambing) dan olahannya (yogurt, tofu). Kadar protein diukur dengan metode Lowry, sedangkan profil protein dianalisis menggunakan SDS PAGE. Data yang diperoleh dianalisis secara deskriptif. Kadar protein tertinggi pada sampel yang dianalisis terdapat pada produk yogurt A (579,5 mg/ml), disusul susu kedelai (289,99 mg/ml) dan susu kambing (133,1 mg/ml). Analisis profil protein terlihat pita protein dengan mobilitas terendah sampai tertinggi terletak pada berat molekul 14-150 KDa. Pita protein khas yang hanya dimiliki susu kambing adalah pita 150kDa. Sementara pita protein khas yang hanya dimiliki susu kedelai adalah pita 44 kDa dan 55kDa. Pita protein yang khas hanya dimiliki yogurt A (dengan bakteri Lactobacillus bulgaricus dan Streptococcus thermophillus) adalah pita 65Da. Semua jenis susu dan olahannya memiliki pita 70kDa, kecuali susu kedelai. Profil protein susu kedelai dan tofu menunjukkan profil protein yang sangat berbeda, namun keduanya memiliki pita 18kDa.
This study aimed to observe protein level and profiles on some milks (soy milk, goat's milk) and dairy (yogurt, tofu) product. Protein content was observed by Lowry method, whereas the protein profiles were analyzed by polyacrylamide gel electrophoresis. Data were analyzed descriptively. The highest protein content of the observed sample was in yogurt A products (579,5 mg/ml), followed by soy milk (289,99 mg/ml) and goat's milk (133,1 mg/ml). Analysis of protein profiles showed protein bands with lowest to highest mobility lies in the molecular weight of 14-150 KDa. Typical protein band of goat's milk was a 150kDa band. While the typical protein bands of soy milk were 44 kDa and 55kDa band. The typical protein band of yogurt A (with Lactobacillus bulgaricus and Streptococcus thermophillus bacterium) was 65Da. All types of milks and dairy had 70kDa band, except for soy milk. Protein profile of soy milk and tofu was very different, but both had 18kDa band.
Keywords
Full Text:
PDFReferences
Bonizzi I, Buffoni JN, & Feligini M. 2009. Quantification of bovine casein fractions by direct chromatographic analysis of milk. J Chromatography. 1216(1):165-168
Carroccio A, Cavataio F, Montalto G, D’Amico D, Alabrese L, & Iacono G. 2000. Intolerance to hydrolysed cow’s milk proteins in infants: clinical characteristics and dietary treatment. Clin Exp Allergy 30: 1597-1603
Carroll KK. 1991. Review of clinical studies on cholesterol-lowering response to soy protein. J Am Diet Ass. 91: 820-7.
Cavalli SV, Silva SV, Cimino C, Malcata FX, & Priolo N. 2006. Hydrolysis of caprine and ovine milk proteins, brought about by aspartic peptidases from Silybum marianum flowers: Argentina-Portugal. pp.1-7
Chilliard Y, Ferlay A, Rouel J, & Lamberet G. 2003. A review of nutritional and physiological factors affecting goat milk lipid synthesis and lipolysis. J Dairy Sci 86 (5): 1751-1770
Cozma A, Andrei S, Miere D, Filip L, & Loghin F. 2011. Proteins profile in milk from three species of ruminants. Not Sci Biol 3(1):26-29
Diftis N & Kiosseoglou V. 2006. Stability against heat-induced aggregation of emulsions prepared with a dry-heated soy protein isolate-dextran mixture. J Food Hydrocolloids 20(6): 787-792
Docena GH, Ferandez R, Chirdo FG, & Fossati CA. 1996. Identification of casein as the major allergenic and antigenic protein of cow’s milk. Allergy 51: 412-416
Effendi MH, Hartini S, & Lusiastuti AM. 2009. Peningkatan kualitas yogurt dari susu kambing dengan penambahan bubuk susu skim dan pengaturan suhu pemeraman. J Penelit Med Eksakta 8(3):185-192.
Greppi GF, Roncada P, & Fortin R. 2008. Protein components of goat’s milk. Dairy goats feeding and nutrition. pp :71-94
Haenlein GFW. 2004. Goat milk in human nutrition. J Small Rumres. 51(2):155-163
Hames & Rickwood. 1990. Gel Electrophoresis of Proteins A Practical Approach. Third Edition. New York: Oxford University Press
Heyman M & Desjeux JF. 1992. Significance of intestinal food protein transport. J Pediatr Gastroent Nutr 15: 48-57.
Hidayat E, Kinayungan I, Irhas M, Sidiq F, & Susanti R. 2015. Analysis of proximate and protein profile of kefir from fermented goat and cow milk. Biosaintifika 7(2): 87-91
Jovanovic S, Barac M, Macej O, Vucic T, & Lacnjevac C. 2007. SDS-PAGE analysis of soluble proteins in reconstituted milk exposed to different heat treatments. Sensors 7: 371-383
Khalil AA. 2006. Nutritional improvement of an Egyptian breed of mung bean by probiotic lactobacilli. J Biotechnology 5(2):206-212.
Khoiriyah LK & Fatchiyah F. 2013. Karakter biokimia dan profil protein yogurt kambing pe difermentasi bakteri asam laktat. J Exp Life Sci 3(1): 1-6.
Kustyawati ME, Susilawi, Tobing D, & Trimaryanto. 2012. Profil asam lemak dan asam amino susu kambing segar dan terfermentasi. J Teknol dan industri Pangan. 23(1): 47-52
Lowry O, Rosebrough HNJ, Farr AL, & Randal RJ. 1951. Protein measurement with the folin phenol reagent. J Biol Chem. 193: 265-275
Marshall K. 2004. Therapeutic applications of whey protein. Altern Med Rev 9(2):136-56
Miranda G, Mahé M, Leroux C, Martin P. 2004. Proteomic tools to characterize the protein fraction of Equidae milk. Proteomics 4:2496-2509.
Mitsuoka T. 1976. Taxonomy of lactic acid bacteria and medical effect of sour milk. Jap J Dairy Food Sci 25: A170-6.
Muradyan EA, Erzhynkyan LA, & Sapondzhyan MS. 1986. Composition of three amino acids in fermented milk product. Biologicheskii-Zhurnal-Armenil 29: 111-112
Ng-Kwai-Hang KF. 2003. Milk proteins-heterogeneity, fractionation and isolation. In: Roginski H, Fuquay JW, Fox PF, editors, Encyclopedia of Dairy Sciences. London: Academic Press. pp. 1881-1894
Nisa FZ, Marsono Y, Harmayani E. 2007. Efek hipokolesterolemik susu kedelai fermentasi steril secara in vitro. Berita kedokteran masyarakat 23(2): 47-51
Nitsche R. 2011. Milk protein analysis with the Agilent 2100 Bioanalyzer and the Agilent Protein 80 kit. Germany: Agilent Technologies, Inc.
Oberman H. 1985. Microbiology of Fermented Food. Elsevier Applied Sci. Published. London and New York. Pp 25-29.
Osman MA, Rahman EIEA, & Dirar HA. 2010. Biochemical changes occuring during fermentation of camel milk by selected bacterial starter cultures. African J Biotechnol 9: 7331-7336
Pacheco MTB, Costa Antunes AE, & Sgarbieri VC. 2008. New Technological and physiological functional properties of milk proteins. In: Boscoe AB, Listow CR, editors, Protein Research Progress. New York: Nova Science Publishers Inc. pp. 117-168
Padaga M, Savitry ME, & Murwani S. 2009. Potensi Protein Spesifik Susu Kambing Sebagai Immunomodulator Dan Immunogen: Upaya Pengembangan Pangan Nutrasetika: Laporan Penelitian. http://elib.pdii.lipi.go.id/katalog/index.php/searchkatalog/byId/ 60212. Diakses tanggal 12 November 2012
Pasquini M, Tommei B & Mattii S. 2011. Buffalo milk: proteins electrophoretic profile and somatic cell count. Ital J Anim Sci 2(1S):299-301
Pelmus RS, Pistol GC, Lazar C, Marin DE, Gras M, Radu M & Ghita E. 2012. Preliminary study on milk composition and milk protein polymorphism in the romanian local sheep breed teleorman black head tsigai. Rom Biotech Lett 17(5): 75-83.
Potter SM. 1995. Overview of possible mechanisms for the hypocholesterolemic effect of soy perotein. J Nutr 125: 606S-611S
Ramchandran L, Sciences H & Campus W. 2009. Low-fat yoghurt as influenced by fat replacer. Faculty of Health, Engineering and Science Victoria University. Australia
Safitri MF & Swarastuti A. 2011. Kualitas kefir berdasarkan konsentrasi kefir grain. Jurnal Aplikasi Teknologi Pangan 2(2):87-92
Schanbacher FL, Talhouk RS, Murray FA, Gherman LI, & Willett LB. 1998. Milk-borne bioactive peptides. Int Dairy J 8: 393-403.
Sodiq A & Abidin Z. 2008. Meningkatkan produksi susu kambing peranakan etawa. PT. Agro Media Pustaka. Jakarta.
Susilorini TE, Sawitri ME, Muharlien. 2009. Budidaya 22 Ternak Potensial. Penebar Swadaya. Jakarta
Tanaka T. 2007. Antimicrobial activity of lactoferrin and lactoperoxidase in milk. In: Ling JR, editor, Dietary Proteins Research Trends. New York: Nova Science Publishers Inc. pp. 101-115.
Tay EP & Gam LH. 2011. Proteomics of human and the domestic bovine and caprine milk. J Mol Biol Biotechnol 19: 45-53.
Van Boekel MAJS. 2001. Kinetic aspects of the maillard reaction: A critical review. J Nahrung 45 :150-159
Verdamuthu ER. 1982. Fermented milk dalam economic microbiology. Fermented Food Vol 7. Edited by AH Rose. Uzadenic Press. London. Pp:200-215
Zevchak SE. 2007. The impact of agglomeration on flavor and flavor stability of whey proteins. The Thesis. The Graduate Faculty of North California States University. United States of America.
Refbacks
- There are currently no refbacks.
This work is licensed under a Creative Commons Attribution 4.0 International License.