HALOFİLİK LAKTİK ASİT BAKTERİLERİ VE GIDA SANAYİSİNDE KULLANIM ALANLARI

Yıl 2015, Cilt: 40 Sayı: 6, 349 - 356, 01.12.2015

Seda Tahtacı Gülden Başyiğit Kılıç

Öz

Halofilik laktik asit bakterileri (HLAB), gelişmeleri için tuza gereksinim duyan, yüksek tuz konsantrasyonunu(>%18) tolere edebilen veya tuz-seven bakteriler olarak tanımlanmaktadır. HLAB, tuz içeriği yüksekfermente gıdalarda görülen baskın mikroorganizmalardır. Özellikle Tetragenococcus ve Pediococcustürlerinin fermantasyonda önemli rol oynadıkları bilinmektedir. Yapılan çalışmalarda Tetragenococcushalophilus, Tetragenococcus muriaticus, Pediococcus pentosaceus ve Lactobacillus plantarum türleriyaygın olarak tespit edilmiştir. HLAB, başlatıcı kültür olabilme, aroma bileşenleri ve organik asit üretebilmeözelliklerinden dolayı gıda endüstrisinde önemli yere sahiptir. Bu bakteriler tarafından üretilen laktikasit ve asetik asit gibi organik asitler patojen mikroorganizmaların gelişmesini inhibe ederek üründebozulmayı azaltır, aynı zamanda lezzet gelişimine katkıda bulunur. Ayrıca bu mikroorganizmalartarafından üretilen β-karoten, poli-β-hidroksialkonat, ekzopolisakkaritler, enzimler, ektoin ve gliserolgibi belli özel bileşikler endüstride kullanılmaktadır. Bu derleme çalışmasında gıda sanayisinde önemliyere sahip olan HLAB hakkında bilgi verilmiş, bu bakterilerin üretimde kullanılmalarına yönelik yapılmışçalışmalardan örnekler sunulmuştur

Anahtar Kelimeler

Halofilik laktik asit bakterileri, tuz, ürün geliştirme

HALOPHILIC LACTIC ACID BACTERIA AND THEIR APPLICATION IN THE FOOD INDUSTRY

Öz

Halophilic lactic acid bacteria (HLAB) are microorganisms that can live in high salt concentrations(>18%) and they are described as salt-loving bacteria. HLAB are dominant bacteria in the fermentedfoods contain higher salt. Especially Tetragenococcus and Pediococcus species play important role inthe fermantation. Tetragenococcus halophilus, Tetragenococcus muriaticus, Pediococcus pentosaceusand Lactobacillus plantarum species have been commonly determined in previous studies. HLAB aresignificant in food industry due to produce flavoring components, organic acid and to be starter culture.Organic acids such as lactic acid and acetic acid produced by these bacteria reduce spoilage of productsby inhibiting pathogenic microorganisms, and also contribute to development of flavor. In addition tothese features, certain specific compounds as β-carotene, poly-β-hidroxyalconate, exopolysaccharides,enzymes, ectoine and glycerol are used in industry. In this review, information is given about HLABand previous studies in this area were reviewed

Anahtar Kelimeler

Halophilic lactic acid bacteria, salt, product development

Kaynakça

• Başyiğit Kılıç G, Kuleaşan H, Eralp İ, Karahan AG. 2009. Manufacture of Turkish Beyaz cheese added with probiotic strains. LTW-Food Sci Technol, 42, 1003-1008.
• Sağdıç O, Öztürk İ, Cankurt H, Tornuk F. 2011. Interaction between some phenolic compounds and probiotic bacterium in functional ice cream production. Food Bioprocess Tech, DOI 10.1007/s11947-011-0611-x.
• Larsen H. 1962. The Bacteria: a Treatise on Structure and Function, Akademik baskı, I.C. Gunsalus, R.Y. Stainer (editörler), Newyork, 297-342. 4. Oren A. 2010. Industrial and environmental applications of halophilic microorganisms, Envi- ron Technol, 31, 8-9, 825-834.
• Rattanachaikunsopon P, Phumkhachorn P. 2010. Lactic acid bacteria: Their antimicrobial compounds and their uses in food production, Annals of Biological Research, 1 (4), 218-228.
• Yılmaz M, Yuvalı Çelik G. 2007. Bakteriyel Ekstraselüler Polisakkaritler (EPS), Orlab On-Line Mikrobiyoloji Dergisi, 05, 2, 7-13.
• Mueller L., Boehm V. 2011. Antioxidant activity of β-carotene compounds in different in vitro assays. Molecules. 16, 1055-1069; doi:10.3390/ molecules1602105.
• Nwodo U.U, Green E, Okoh A.I. 2012. Bacterial exopolysaccharides: Functionality and prospects, Int. J. Mol. Sci., 13, 14002-14015; doi:10.3390/ ijms131114002. Review
• Kunte H.J, G Lentzen, Galinski E.A. 2014. Industrial production of the cell protectant ectoine: Protection mechanisms, processes, and products, Current Biotechnology, 3, 1, 10-25(16).
• Uchida M, Miyoshi T, Yoshida G, Niwa K, Mori M., Wakabayashi H. 2014. Isolation and characterization of halophilic lactic acid bacteria acting as a başlatıcı culture for sauce fermentation of the red alga Nori (Porphyra yezoensis), J Appl Microbiol, ISSN 1364-5072.
• Justé A, Van Trappen S, Verreth C, Cleen- werck I, De Vos P, Lievens B, Willems K.A. 2012. Characterization of Tetragenococcus strains from sugar thick juice reveals a novel species, Tetragenococcus osmophilus sp. nov., and divides Tetragenococcus halophilus into two subspecies, T. halophilus subsp. halophilus subsp. nov. and T. halophilus subsp. flandriensis subsp. nov., Int J Syst Evol Microbiol., 62(1):129-37. doi: 10.1099/ ijs.0.029157-0.
• Holzapfel W.H, Franz C.M.A.P, Ludwig W, Back W, Dicks L.M.T. 2006. The genera Pediococcus and Tetragenococcus, The Prokaryotes, 229-266.
• Lahtinen S (ed), Ouwehand A.C (ed), Salminen S (ed), Wright von A (ed). 2011. Lactic Acid Bacteria: Microbiological and Functional Aspects, CRC Press, s. 98-99.
• Justé A, Lievens B, Rediers H, Willems K.A. 2014. Genus Tetragenococcus, Chapter 16.
• Vos P, Garrity G, Jones D, Krieg N.R, Ludwig W, Rainey F.A, Schleifer K.-H, Whitman W.B. 2011. Bergey's Manual of Systematic Bacteriology: Volume 3: The Firmicutes. New York, s. 611-616. 16. Dobson C.M, Deneer H, Lee S. Hemmingsen S, Glaze S, Ziola B. 2002. Phylogenetic analysis of the genus Pediococcus, including Pediococcus claussenii sp. nov., a novel lactic acid bacterium isolated from beer, Int J Syst Evol Microbiol. 52:2003-2010.
• Zajc J, Kogej T, Galinski E.A, Ramos J, Cimerman N.G. 2014. Osmoadaptation strategy of the most halophilic fungus, Wallemiaichthyophaga, growing optimally at salinities above 15% NaCl, Appl Environ Microbiol., 80, 1, 247-256.
• Reshetnikov A.S, Khmelenina V.N, Mustahimov I.I, Klayuzhnaya M, Lidstrom M. Trotsenko Y.A. 2011. Diversity and phylogeny of the ectoine biosynthesis genes in aerobic, moderately halophilic methylotrophic bacteria. Extremophiles, 15, 6, 653-663.
• Shivan P, Mugeraya G. 2011. Halophilic bacteria and their compatible solutes– osmoregulation and potential applications, Curr Sci., 100, 10.
• López-Pérez M, Ghai R, Leon M.J, Olmos- Rodríguez Á, Copa-Patiño J.L, Soliveri J, Sanchez- Porro C,Ventosa A, Rodriguez-Valera F. 2013. Genomes of "Spiribacter", a streamlined, successful halophilic bacterium. BMC Genomics, 14:787.
• Satomi M, Kimufu B, Mizoi M, Sato T, Fujii T. 1997. Tetragenococcus muriaticus sp. nov., a new moderately halophilic lactic acid bacterium isolated from fermented squid liver sauce, International Journal Of Systematic Bacteriology, 47, 3, 832-836.
• Chen Y.-S, Yanagida F, Hsu J.-S. 2006a. Isolation and characterization of lactic acid bacteria from suan-tsai (fermented mustard), a traditional fermented food in Taiwan, J Appl Microbiol., 101, 125-130, doi:10.1111/j.1365-2672.2006.02900.x
• Chen Y.-S, Yanagida F, Hsu J.-S. 2006b. Isolation and characterization of lactic acid bacteria from dochi (fermented black beans), a traditional fermented food in Taiwan, Lett Appl Microbiol., 43, 2, 229-235.
• Chao S.-H, Tomii Y, Watanabe K, Tsai Y.-C. 2008. Diversity of lactic acid bacteria in fermented brines used to make stinky tofu, Int J Food Microbiol., 123, 134-141.
• Chao S.-H, Wu R.-J, Watanabe K, Tsai Y.-C. 2009. Diversity of lactic acid bacteria in suan-tsai and fu-tsai, traditional fermented mustard products of Taiwan, Int J Food Microbiol., 135, 203-210.
• Cui Y, Qu X, Li H, He S, Liang H, Zhang H. 2012. Isolation of halophilic lactic acid bacteria from traditional Chinese fermented soybean paste and assessment of the isolates for industrial potential, Eur Food Res Technol, 234:797-806.
• Thokchom S, Joshi S.R. 2013. Physicochemical analysis of ethnically fermented soybean products of North-East India and molecular characterization of associated lactic acid bacteria, Proc Natl Acad Sci India Sect B Biol Sci., DOI 10.1007/s40011- 013-0199-1.
• Kim M.-S, Park E.-Jin. 2014. Bacterial communities of traditional salted and fermented seafoods from Jeju Island of Korea using 16S rRNA gene clone library analysis, J Food Sci., 79, 5.
• Fukui Y, Yoshida M, Shozen K-İ,Funatsu Y, Takana T, Oikawa H, Yano Y, Satomii M. 2012. Bacterial communities in fish sauce mash using culture-dependent and -independent methods, J Gen Appl Microbiol., 58, 273-281.
• Bonomo M.G, Ricciardi A, Salzano. 2011. Influence of autochthonous starter cultures on microbial dynamics and chemical-physical features of traditional fermented sausages of Basilicata region, World J Microbiol Biotechnol., 27, 1,137-146.
• Udomsil N, Rodtong S, Tanasupawat S, Yongsawatdigul J. 2010. Proteinase-producing halophilic lactic acid bacteria isolated from fish sauce fermentation and their ability to produce volatile compounds, Int J Food Microbiol., 141, 186-194.
• Sakaguchi K. Tetragenococcus halophilus NBRC 12172. http://www.bio.nite.go.jp/ngac/e/th1-e.html (Erişim Tarihi: 21 Ocak 2015)
• Quintana M.C, Garcia P.G, Fernandez A.G. 1999. Establishment of conditions for green table olive fermentation at low temperature, Int J Food Microbiol., 51, 133-143.
• Korukluoğlu M, Gürbüz O, Şahin İ. 2002. Taze zeytin mikroflorasında bulunan laktik asit bakterilerinin belirlenmesi, Tarım Bilimleri Dergisi, 8 (2) 109-113.
• Uchida M, Uchida M, Ou J, Chen B.-W, Yuan C.-H, Zhang X.-H, Chen S.-S, Funatsu Y, Kawasaki K.-I, Satomi M, Fukuda Y. 2005. Effects of soy sauce koji and lactic acid bacteria on the fermentation of fish sauce from freshwater silver carp Hypophthalmichthys molitrix, Fish Sci., 71, 422-430. 36. Lee J.-Y, Kim C.-J, Kunz B. 2006. Identification of lactic acid bacteria isolated from kimchi and studies on their suitability for application as starter culture in the production of fermented sausages, Meat Sci., 72, 437-445.
• Bagenda D.K, Hayashi K, Yamazaki K, Kawai Y. 2008. Characterization of an antibacterial substance produced by Pediococcus pentosaceus Iz3.13 isolated from Japanese fermented marine food, Fish Sci., 74, 2, 439-448.
• Morales F, Morales I.J, Hernandez C.H. 2011. Isolation and partial characterization of halotolerant lactic acid bacteria from two Mexican cheeses. Appl Biochem Biotechnol., 164:889-905.
• Lee K.E, Lee S.M, Choi Y.H, Hurh B.S, Kim Y.-S. 2013. Comparative volatile profiles in soy sauce according to inoculated microorganisms, Biosci, Biotechnol, Biochem, 77(11), 2192-2200.
• Gildberg A, Thongthai C. 2008. The effect of reduced salt content and addition of halophilic lactic acid bacteria on quality and composition of fish sauce made from sprat, Journal of Aquatic Food Product Technology, 10:1, 77-88.
• Satomi M, Furushita M, Oikawa H, Yano Y. 2011. Diversity of plasmids encoding histidine decarboxylase gene in Tetragenococcus spp. isolated from Japanese fish sauce, Int J Food Microbiol., 148, 60-5.
• Onda T, Yanagida F, Uchimura T, Tsuji M, Ogino S, Shinohara T, Yokotsuka K. 2003. Analysis of lactic acid bacterial flora during miso fermentation, Food Sci Technol Res., 9 (1), 17-24. 43. Ishikawa M, Yamasato K, Kodama K, Yasuda H, Matsuyama M, Okamoto Kainuma A, Koizumi Y, Yasuda H, Matsuyama M. 2013. Alkalibacterium gilvum sp. nov., slightly halophilic and alkaliphilic lactic acid bacterium isolated from soft and semi- hard cheeses, Int J Syst Evol Microbiol., 63, 1471-1478, doi: 10.1099/ijs.0.042556-0.
• Naila A, Flint S, Fletcher G, Bremer P, Meerdink G. 2010. Control of biogenic amines in food— existing and emerging approaches, J Food Sci., 75, 7. 45. Stadnik J, Dolatowski Z.J. 2010. Biogenic amines in meat and fermented meat products, Acta Sci Pol Technol Aliment., 9(3), 251-263.
• Visciano P, Schirone M, Tofalo R, Suzzi G. 2012. Biogenic amines in raw and processed seafood. Review Article. doi: 10.3389/fmicb.2012.00188.
• Collins J.D, Noerrung B, Budka H, Andreoletti O, Buncic S, Griffin J, Hald T, Havelaar A, Hope J, Klein G,Koutsoumanis K, McLauchlin J, Müller- Graf C, Nguyen-The C, Peixe L, Maradona M.P, Ricci A, Sofos J, Threlfall J, Vågsholm I, Vanopdenbosch E. 2011. Scientific opinion on risk based control of biogenic amine formation in fermented foods, EFSA Journal, 9(10), 2393.
• Spano G, Russo P, Lonvaud-Funel A, Lucas P, Alexandre H, Grandvalet C, Coton E, Coton M, Barnovon L, Bach B, Rattry F, Bunte A, Magni C, Ladero V, Alvarez M, Fernandez M, Lopez P, Palencia de P.F, Corbi A, Trip H, Lolkema J.S. 2010. Biogenic amines in fermented foods. Eur J Clin Nutr., 64, 95-100.
• Kimura B, Konagaya Y, Fujii T. 2001. Hista- mine formation by Tetragenococcus muriaticus, a halophilic lactic acid bacterium isolated from fish sauce, Int J Food Microbiol., 70,1-2, 71-77
• Françoise L. 2010. Occurrence and role of lactic acid bacteria in seafood products, Int J Syst Evol Microbiol., 27, 6, 698–709, doi: 10.1016/j.fm. 2010.05.016.
• Tsai Y.-H, Lin C.-Y, Chang S.-C, Chen H.-C., Kung H.-F, Wei C.-I, Hwang D-F. 2005. Occurrence of histamine and histamine-forming bacteria in salted mackerel in Taiwan, Food Microbiol., 22, 461-467 52. Kuda T, Izowa Y, Ishii S, Takahashi H, Torido Y, Kimura B. 2012. Suppressive effect of Tetragenococcus halophilus, isolated from fish-nukazuke, on histamine accumulation in salted and fermented fish, Food Chem, 130, 3, 569-574.
• Mah J.-H., Hwang H.-J. 2009. Effects of food additives on biogenic amine formation in Myeolchi-jeot, a salted and fermented anchovy (Engraulis japonicus), Food Chem., 114, 1, 168–173.
• Dubey R, Kumar K, Agrawala D, Char T, Pusp P. 2011. Isolation, production, purification, assay and characterization of fibrinolytic enzymes (Nattokinase, Streptokinase and Urokinase) from bacterial sources, Afr J Biotechnol., 10(8), 1408-1420.
• Borah D, Yadav R.N.S, Sangra A, Shahin L, Chaubey A.K. 2012. Production, purification and characterization of nattokinase from Bacillus subtilis, isolated from tea garden soil samples of Dibrugarh, Assam, Asian J of Pharmaceutical and Clinical Research, 5,3.
• Lu C.-L, Chen S.-N. 2012. Fibrinolytic enzymes from medicinal mushrooms. Protein Structure, Eshel Faraggi E. (baş editör), InTech, s. 337-362.
• Aradhye P.K, Chavan M.D. 2014. Production and characterization of fibrinolytic enzyme from Aspergillus niger, World Journal of Pharmacy and Pharmaceutical Sciences, 3,9, 843-851.
• Prihanto A, Darius Firdaus M. 2013. Proteolytic and fibrinolytic activities of halophilus lactic acid bacteria from two Indonesian fermented foods, Journal of Microbiology, Biotechnology and Food Sciences, 2 (5) 2291-2293.
• Watanabe F, Miyamoto E, Tanioka Y, Enomoto T, Kuda T, Nakano Y. 2006. TLC analysis of corrinoid compounds in the halophilic lactic acid bacterium Tetragenococcus halophilus, J Liq Chromatogr Relat Technol., 29:14, 2153-2158.