L-asparaginase merupakan enzim yang mengubah L-asparagin menjadi L-aspartat. L-asparagin dapat dimanfaatkan oleh sel kanker leukemia sebagai salah satu sumber nutrisinya. Penambahan L-asparaginase dapat menghambat pertumbuhan sel kanker. Penggunaan L-asparaginase dalam skala industri lebih mengutamakan L-asparaginase yang memiliki aktivitas dan stabilitas optimum di suhu tinggi, karena kecepatan reaksi dalam menghidrolisis L-asparagin tinggi, stabil dari denaturan misalnya detergen dan senyawa organik, dan stabil pada kondisi asam maupun basa. L-asparaginase yang memiliki aktivitas dan stabilitas di suhu tinggi dapat dieksplorasi dari mikroorganisme yang hidup di lingkungan yang bersuhu dan bersalinitas tinggi. Tujuan penelitian ini adalah untuk memperoleh isolat bakteri termohalofilik penghasil enzim L-aparaginase dari sumber air panas Wawolesea dan untuk mengetahui aktivitas enzim L-asparaginase yang dihasilkannya. Bakteri termohalofilik penghasil enzim L-asparaginase diperoleh dengan tahapan: isolasi bakteri pada media NA yang mengandung NaCl 1,5% – 1,6%; seleksi bakteri penghasil L-asparaginase pada media M-9; produksi L-asparaginase dengan prinsip fermentasi pada media produksi serta pengukuran aktivitas dan aktivitas spesifik enzim L-asparaginase. Hasil isolasi menunjukkan adanya 14 isolat bakteri termohalofilik yang mampu menghasilkan enzim L-asparaginase. Aktivitas enzim L-asparaginase tertinggi yaitu 86,61 IU/mL pada isolat AAT3.2 dan terendah yaitu 38,24 IU/mL pada isolat CAT1.1. Aktivitas spesifik tertinggi 6767,98 IU/mg pada isolat CAT3.2 dan terendah 684,54 IU/mg pada isolat CAT1.1.

Screening of L-asparaginase-Producing Thermohalophilic Bacteria from Wawolesea Hot Springs in Southeast Sulawesi and Their Enzyme Activity Test. The L-asparaginase is an enzyme that can convert L-asparagine to L-aspartate. L-asparagine can be utilized by leukemia cancer cells as a source of nutrition. The use of L-asparaginase on an industrial scale prioritizes L-asparaginase that exhibits optimal activity and stability at high temperatures due to the high reaction rate in hydrolyzing L-asparagine, stability against denaturants such as detergents and organic compounds, and stability under acidic or basic conditions. L-asparaginase with activity and stability at high temperatures can be explored from microorganisms that live in high-temperature and high-salinity environments. This study aimed to obtain isolates of thermohalophilic bacteria that produce L-asparaginase enzymes from Wawolesea hot springs and determine the activity of the L-asparaginase enzymes. Thermohalophilic bacteria producing L-asparaginase from Wawolesea hot springs were obtained by the following steps: isolation of bacteria on NA (Nutrient Agar) media containing 1.5% – 1.6% NaCl, selection of L-asparaginase-producing bacteria on M-9 media, production of L-asparaginase with the principle of fermentation on production media and measurement of activity and specific activity of L-asparaginase enzyme. The isolation results showed that there were 14 isolates of thermohalophilic bacteria capable of producing L-asparaginase. The highest L-asparaginase enzyme activity was 86.61 IU/mL in AAT3.2 isolates, and the lowest was 38.24 IU/mL in CAT1.1 isolates. The highest specific activity was 6767.98 IU/mg in isolate CAT3.2, and the lowest was 684.54 IU/mg in isolate CAT1.1.

Ahmad, A., Patta, A. M., and Natsir, H., 2013. Purification and Immobilization of L-asparaginase Enzyme From the Thermophilic Bacteria Bacillus licheniformis Strain HSA3-1a. Journal of Pharma and Bio Sciences, 4(4), 277‒278.

Alrumman, S. A., Mostafa, Y. S., Al-izran, K. A., Alfaifi, M. Y., Taha, T. H., and Elbehairi, S. E., 2019. Production and Anticancer Activity of an L-Asparaginase from Bacillus licheniformis Isolated from the Red Sea, Saudi Arabia. Scientific Reports 9, 3756. https://doi.org/10.1038/s41598-019-40512-x.

Cachumba, J. J. M., Antunes, F. A. F., Peres, G. F. D., Brumano, L.P., Santos, J. C. D., and Silva, S. S. D., 2016. Current Applications and Different Approaches for Microbial L-asparaginase Production. Brazilian Journal of Microbiology 47, 77–85. https://doi.org/10.1016/j.bjm.2016.10.004.

El-Gendy, M. M. A. A., Awad, M. F., El-Shenawy, F.S., and El-Bondkly, A. M. A., 2021. Production, Purification, Characterization, Antioxidant and Antiproliferative Activities of Extracellular L-asparaginase Produced by Fusarium Equiseti AHMF4. Saudi Journal of Biological Sciences 28(4), 2540‒2548. https://doi.org/10.1016/j.sjbs.2021.01.058.

El-Naggar, N. E., Deraz, S. F., Soliman, H. M., El-Deeb, N. M., and El-Ewasy, S. M., 2016. Purification, Characterization, Cytotoxicity and Anticancer Activities of L-asparaginase, Anti-colon Cancer Protein, from The Newly Isolated Alkaliphilic Streptomyces Fradiae NEAE-82. Science Report 6(32926). https://doi.org/10.1038/srep32926.

Gosh, S. S., Murthy, S., Govindasamy, and Chandrasekaran, C., 2013. Optimization of L-Asparaginase Production by Serratia marcescens (NCIM 2919) Under Solid State Fermentation Using Coconut Oil Cake. Journal Sus. Chem. Prosc 1, 1‒9. https://doi.org/10.1186/2043-7129-1-9

Hadinoto, S., dan Syukroni, I., 2019. Pengukuran Protein Terlarut Air Cucian Gelembung Renang dan Kulit Ikan Tuna Menggunakan Metode Bradford. Majalah BIAM 15(01), 15‒20.

Hänelt, I., and Müller, V., 2013. Molecular Mechanisms of Adaptation of the Moderately Halophilic Bacterium Halobacillis halophilus to Its Environment. Life 3, 234‒243. https://doi.org/10.3390%2Flife3010234.

Jamaluddin, Alfin, Muzuni, dan Yanti, N. A., 2018. Eksplorasi Bakteri Termohalofilik Penghasil L-Asparaginase di Sumber Air Panas Wawolese Sulawesi Tenggara, Biowallacea: Journal of Biological Research 5(1), 1‒9

Jamaluddin dan Umar, E. P., 2017. Karakteristik Fisik dan Kimia Mata Air Panas Daerah Barasangka Kabupaten Konawe Utara Provinsi Sulawesi Tenggara. Jurnal Geo Celebes 1(2), 62‒65. https://doi.org/10.20956/geocelebes.v1i2.2291.

Jia, R., Wan, X., Geng, X., Xue, D., Xie, Z., Chen, C., 2021. Microbial L-asparaginase for Application in Acrylamide Mitigation from Food: Current Research Status and Future Perspectives. Microorganisms 9, 1659. https://doi.org/10.3390%2Fmicroorganisms9081659.

Kurniawati, L., Kusdiyantini, E., dan Wijanarka, 2019. Pengaruh Variasi Suhu dan Waktu Inkubasi Terhadap Aktivitas Enzim Selulase dari Bakteri Serratia marcescens. Jurnal Akademika Biologi 8(1), 1‒9

Martínez, G. M., Pire, C., and Martínez-Espinosa, R. M., 2022. Hypersaline Environments as Natural Sources of Microbes with Potential Applications in Biotechnology: The Case of Solar Evaporation Systems to Produce Salt in Alicante County (Spain). Current Research in Microbial Sciences 3, 100136. https://doi.org/10.1016/j.crmicr.2022.100136.

Muzuni, Suriana, Yanti, N. A., and Ardiansyah, 2022. Phenotypic Characterization and Identification of Potential L-Asparaginase-Producing Thermohalophilic Bacteria from Wawolesea Hot Spring, North Konawe, Southeast Sulawesi, Indonesia. Pakistan Journal of Biological Sciences 25(11), 1021‒1032. https://doi.org/10.3923/pjbs.2022.1021.1032.

Patta, A.M., Ahmad, A., dan Natsir, H., 2013. Produksi, Pemurnian Parsial, dan Karakterisasi L-asparaginase dari Bakteri Termofilik Bacillus Licheniformis Strain Hsa3-1a, Tesis, Universitas Hasanuddin, Makassar.

Pradhan, B., Dash, S. K., and Sahoo, S., 2013. Skrining and Characterization of Extracelluar L-asparaginase producing Bacillus subtilis strain hswx88, Isolated from Taptapani Hotspring of Odisha, India. Journal Trop Biomed 3(12), 936‒941 https://doi.org/10.1016/s2221-1691(13)60182-3.

Poernomo, A.T., Sudjarwo dan Parasati, R. A., 2014, Purifikasi Parsial Enzim Fibrinolitik Tempe Kacang Koro (Canavalia ensiformis) Produk Fermentasi Rhizopus oryzae FNCC 6078, Jurnal Berkala Ilmiah Farmasi 3(2), 23‒30

Qeshmi, F.I., Homaei, A., Fernandes, P., and Javadpour, S., 2018. Marine Microbial L-Asparaginase: Biochemistry, Molecular Approaches and Applications in Tumor Therapy and in Food Industry. Microbiological Research 208, 99‒112. https://doi.org/10.1016/j.micres.2018.01.011.

Rubiano-Labrador, C., Bland, C., Miotello, G., Armengaud, J., and Baena, S., 2015. Salt Stress Induced Changes in the Exoproteome of the Halotolerant Bacterium Tistlia consotensis Deciphered by Proteogenomics. PLoS ONE 10(8). https://doi.org/10.1371/journal.pone.0135065.

Siciliano, C. C., Dinh, V. M., Canu, P., Mikkola, J-P., and Khokarale, S. G., 2023. Efficient Adsorption and Catalytic Reduction of Phenol Red Dye by Glutaraldehyde Cross-Linked Chitosan and Its Ag-Loaded Catalysts: Materials Synthesis, Characterization and Application. Clean Technologies 5(2), 466‒483. https://doi.org/10.3390/cleantechnol5020024.

Singh, Y. R., Kumar, V., Gundampati, S., Jagannadham, and S. K., Srivastava, 2013. Extracelullar L-asparaginase from a Protease-Deficient Bacillus aryabhattai ITBHU02: Purification, Biochemical Characterization, and Evaluation of Antineoplastic Activity In Vitro. Appl Biochem Biocthenol doi: https://doi.org/10.1007/s12010-013-0455-0.

Straub, C. T., Counts, J.A., Nguyen, D. M. N., Wu, C. H., Zeldes, B. M., Crosby, J. R., Conway, J. M., Otten, J. K., Lipscomb, G. L., Schut, G. J., Adams, M. W. W., and Kelly, R. M, 2018. Biotechnology of Extremely Thermophilic Archaea. FEMS Microbiol Rev. 42(5), 543‒578. https://doi.org/10.1093/femsre/fuy012.

Utami, P., Lestari, S., and Lestari, S. D., 2016. Pengaruh Metode Pemasakan Terhadap Komposisi Kimia dan Asam Amino Ikan Seluang (Rasbora argyotaenia). Jurnal Teknologi Hasil Perikanani 5(1), 73‒84. https://doi.org/10.36706/fishtech.v5i1.3520.