抗生素抗藥性
(Antimicrobial resistance, AMR) 已成為全球公共衛生問題，
長期大量的使用抗生素導致抗藥性菌株出現，使得細菌菌株對抗生素展現出部分
或完全的抵抗力，其中多重抗藥 性轉運 幫浦的過度表達是導致抗藥性的主要機制
之一，因此研究開發 轉運 幫浦抑制劑 (Efflux pump inhibitor, EPI)，被認為是恢復
和擴展治療選擇的策略之一。本篇論文研究旨在透過米麴菌 (Aspergillus oryzae) 固態發酵 (Solid-state fermentation, SSF) 麒麟菜 並 萃取其活性物質， 透過 最小抑
菌濃度試驗 (Minimal inhibitory concentration, MIC) 確認 麒麟菜 萃取物
(Eucheuma perplexum extracts, EPE) 及發酵萃取物 (Eucheuma perplexum fermentation extracts, EPFE) 不 具有 抑制 抗藥性 大腸桿菌 (E.coli Kam3 pSYC- acrB) 生長的能力 。 透過協同試驗 (Modulation assay) 確認 在不同濃度下麒麟菜
萃取物協同四種抗生素 (ciprofloxacin, clarithromycin, erythromycin, tetracycline) 作用 EPE 在 1 μg/mL的濃度下協同 2 倍的 ERY、 CLA; 以及 4倍的 TET、
CIP; EPFE 在 64 和 1 μg/mL 的濃度下分別協同 4 倍的 ERY、 CLA 以及 2 倍
的 TET、 CIP 恢復 抗生素對於 抗藥性 大腸桿菌的敏感性。 螢光累積試驗 的結果
顯示 EPE 及 EPFE 在濃度為 64、 32、 16 對於 EtBr 染劑 沒有螢光累積的效果 ; EPE 及 EPFE 在濃度為 16、 4、 1 對於 H33342 染劑 沒有螢光累積的效果 。 最
後透過 LC 分析 EPE 及 EPFE 中的化學活性成分， 同時透過 分子量、疏水性、
氫鍵供體、氫鍵受體、可旋轉鍵結等特徵歸 納出 具有 開發為 藥物 潛力的 化合物。
綜合上述結果顯示， EPE 及 EPFE 中 並未表現出 轉運幫浦抑制劑之活性 不過
從 EPE 及 EPFE 分析出的酚類、萜類、生物鹼類化合物具有 開發為 臨床 藥物 之
潛力 。

Antimicrobial resistance (AMR) has emerged as a global public health issue due to the prolonged and excessive use of antibiotics, leading to the development of resistant bacterial strains. Overexpression of multidrug resistance efflux pumps is a primary mechanism of this resistance. This study explored the potential of Eucheuma perplexum extracts (EPE) and Eucheuma perplexum fermentation extracts (EPFE), obtained through solid-state fermentation with Aspergillus oryzae, as efflux pump inhibitor (EPI). Minimal inhibitory concentration (MIC) assays confirmed that both EPE and EPFE, at appropriate concentrations, did not inhibit the growth of antibiotic-resistant Escherichia coli (E. coli Kam3 pSYC- acrB). Modulation assays demonstrated that EPE at 1 μg/mL and EPFE at 64 and 1 μg/mL enhanced the efficacy of ciprofloxacin, clarithromycin, erythromycin, and tetracycline, restoring their sensitivity against resistant Escherichia coli. The results of the fluorescence accumulation assay showed that EPE and EPFE at concentrations of 64, 32, and 16 μg/mL did not exhibit fluorescence accumulation with the EtBr dye; similarly, at concentrations of 16, 4, and 1 μg/mL, EPE and EPFE did not show fluorescence accumulation with the H33342 dye. Finally, LC analysis was conducted to identify the bioactive chemical components in EPE and EPFE. Compounds with potential for drug development were characterized based on molecular weight, hydrophobicity, hydrogen bond donors, hydrogen bond acceptors, and rotatable bonds. The overall results indicate that EPE and EPFE did not exhibit efflux pump inhibitor activity. However, the phenolic, terpenoid, and alkaloid compounds identified in EPE and EPFE have potential for development as clinical drugs.

目錄
謝誌 I
摘要 II
Abstract III
表目錄 VI
圖目錄 VII
縮寫表 IX
壹、前言 1
貳、文獻回顧 2
2.1 抗生素 2
2.1.1 抗生素的種類及機制 2
2.1.2 抗生素發展與應用 3
2.1.3 多重抗藥性 (Multidrug resistant, MDR) 4
2.1.4 抗生素抗藥性 (Antimicrobial resistance, AMR) 5
2.2 藥物轉運蛋白 6
2.2.1 轉運蛋白的功能 6
2.2.2 轉運蛋白的分類 6
2.2.3 RND 家族轉運蛋白結構 7
2.2.4 AcrAB-TolC 結構功能及機制 8
2.3 轉運幫浦抑制劑 (Efflux pump inhibitors, EPI) 介紹 9
2.3.1 轉運幫浦抑制劑作用機制 10
2.3.2 轉運幫浦抑制劑的分類與結構特徵 10
2.3.3 研究轉運幫浦抑制劑的方法 17
2.4 藻類 18
2.4.1 藻類簡介 18
2.4.2 麒麟菜 (Eucheuma) 18
2.5 發酵 18
2.5.1 發酵的歷史 18
2.5.2 液態發酵 (Liquid-state fermentation, LSF) 19
2.5.3 固態發酵 (Solid-state fermentation, SSF) 19
2.5.4 真菌固態發酵之生物轉化 19
參、實驗架構 21
肆、材料方法 22
4.1 實驗材料 22
4.1.1 原料 22
4.1.2 菌株來源 22
4.1.3 培養基 22
4.1.4 反應緩衝液 23
4.1.5 抗生素 23
4.1.6 化學藥品 23
4.1.7 實驗儀器與耗材 24
4.2 實驗方法 24
4.2.1 菌株活化 24
4.2.2 孢子液的製備及凍管保存 24
4.2.3 麒麟菜乙醇萃取物之製備 25
4.2.4 麒麟菜培養基製備與發酵 25
4.2.5 真菌計數 25
4.2.6 觀察固態發酵生長情形 25
4.2.7 待測物及抗生素之最小抑菌濃度試驗 (MIC) 25
4.2.8 協同試驗 (Modulation assay) 26
4.2.9 螢光累積試驗 (Accumulation assay) 26
4.2.10 液相層析串聯質譜儀分析方式 (LC-HDMSE) 26
4.2.11 代謝物統計分析 27
4.2.12 藥物代謝動力學分析 (Pharmacokinetics Analysis) 27
4.2.13 統計分析 27
伍、結果與討論 28
5.1 麒麟菜之萃取率與固態發酵 28
5.2 麒麟菜發酵及未發酵萃取物對抗藥性及敏感性大腸桿菌最小抑菌濃度試驗 29
5.3 麒麟菜發酵萃取物與抗生素對抗藥性及敏感性大腸桿菌之協同試驗 29
5.4 螢光染劑累積之情形 30
5.5 LC 分析麒麟菜發酵及未發酵萃取物之結果 31
陸、結論 33
柒、參考文獻 34
捌、圖表 47

Achi, O. (2005). The potential for upgrading traditional fermented foods through biotechnology. African Journal of Biotechnology, 4(5), 375-380.
Ågren, G. I., Wetterstedt, J. M., & Billberger, M. F. (2012). Nutrient limitation on terrestrial plant growth–modeling the interaction between nitrogen and phosphorus. New Phytologist, 194(4), 953-960.
Al-Shawi, M. K. (2011). Catalytic and transport cycles of ABC exporters. Essays in Biochemistry, 50, 63-83.
Arip, M., Selvaraja, M., R, M., Tan, L. F., Leong, M. Y., Tan, P. L., Yap, V. L., Chinnapan, S., Tat, N. C., Abdullah, M., K, D., & Jubair, N. (2022). Review on plant-based management in combating antimicrobial resistance - mechanistic perspective. Frontiers in Pharmacology, 13.
Auria, R., Ortiz, I., Villegas, E., & Revah, S. (1995). Influence of growth and high mould concentration on the pressure drop in solid state fermentations. Process Biochemistry, 30(8), 751-756.
Baugh, S., Phillips, C. R., Ekanayaka, A. S., Piddock, L. J. V., & Webber, M. A. (2014). Inhibition of multidrug efflux as a strategy to prevent biofilm formation. Journal of Antimicrobial Chemotherapy, 69(3), 673-681.
Bentil, J. A., Thygesen, A., Lange, L., Mensah, M., & Meyer, A. S. (2019). Green seaweeds (Ulva fasciata sp.) as nitrogen source for fungal cellulase production. World Journal of Microbiology and Biotechnology, 35(6), 82.
Bentley, R. (2009). Different roads to discovery; Prontosil (hence sulfa drugs) and penicillin (hence β-lactams). Journal of Industrial Microbiology and Biotechnology, 36(6), 775-786.
Blair, J. M., Webber, M. A., Baylay, A. J., Ogbolu, D. O., & Piddock, L. J. (2015). Molecular mechanisms of antibiotic resistance. Nature Reviews Microbiology, 13(1), 42-51.
Blair, J. M. A., Smith, H. E., Ricci, V., Lawler, A. J., Thompson, L. J., & Piddock, L. J. V. (2015). Expression of homologous RND efflux pump genes is dependent upon AcrB expression: implications for efflux and virulence inhibitor design. Journal of Antimicrobial Chemotherapy, 70(2), 424-431.
Bobrowska-Hägerstrand, M., Wróbel, A., Rychlik, B., Bartosz, G., Söderström, T., Shirataki, Y., Motohashi, N., Molnár, J., Michalak, K., & Hägerstrand, H. (2001). Monitoring of MRP-like activity in human erythrocytes: inhibitory effect of isoflavones. Blood Cells, Molecules, and Diseases, 27(5), 894-900.
Bohnert, J. A., & Kern, W. V. (2005). Selected arylpiperazines are capable of reversing multidrug resistance in Escherichia coli overexpressing RND efflux pumps. Antimicrobial Agents and Chemotherapy, 49(2), 849-852.
Bozdogan, B., & Appelbaum, P. C. (2004). Oxazolidinones: activity, mode of action, and mechanism of resistance. International Journal of Antimicrobial Agents, 23(2), 113-119.
Bush, K., & Jacoby, G. A. (2010). Updated functional classification of β-lactamases. Antimicrobial Agents and Chemotherapy, 54(3), 969-976.
Chain, E., Florey, H. W., Gardner, A. D., Heatley, N. G., Jennings, M. A., Orr-Ewing, J., & Sanders, A. G. (1940). Penicillin as a chemotherapeutic agent. The lancet, 236(6104), 226-228.
Chakraborty, K., Joseph, D., Joy, M., & Raola, V. K. (2016). Characterization of substituted aryl meroterpenoids from red seaweed Hypnea musciformis as potential antioxidants. Food Chemistry, 212, 778-788.
Chan, B. C. L., Ip, M., Lau, C. B. S., Lui, S. L., Jolivalt, C., Ganem-Elbaz, C., Litaudon, M., Reiner, N. E., Gong, H., See, R. H., Fung, K. P., & Leung, P. C. (2011). Synergistic effects of baicalein with ciprofloxacin against NorA over-expressed methicillin-resistant Staphylococcus aureus (MRSA) and inhibition of MRSA pyruvate kinase. Journal of Ethnopharmacology, 137(1), 767-773.
Chan, P. T., Matanjun, P., Yasir, S. M., & Tan, T. S. (2014). Antioxidant activities and polyphenolics of various solvent extracts of red seaweed, Gracilaria changii. Journal of Applied Phycology, 27, 2377 - 2386.
Chi, C.-H., & Cho, S.-J. (2016). Improvement of bioactivity of soybean meal by solid-state fermentation with Bacillus amyloliquefaciens versus Lactobacillus spp. and Saccharomyces cerevisiae. LWT - Food Science and Technology, 68, 619-625.
Chukwudi Chinwe, U. (2016). rRNA binding sites and the molecular mechanism of action of the tetracyclines. Antimicrobial Agents and Chemotherapy, 60(8), 4433-4441.
Compagne, N., Vieira Da Cruz, A., Müller, R. T., Hartkoorn, R. C., Flipo, M., & Pos, K. M. (2023). Update on the discovery of efflux pump inhibitors against critical priority gram-negative bacteria. Antibiotics, 12(1), 180.
Corona, A., Sáez, D., & Agosin, E. (2005). Effect of water activity on gibberellic acid production by Gibberella fujikuroi under solid-state fermentation conditions. Process Biochemistry, 40(8), 2655-2658.
D’Costa, V. M., King, C. E., Kalan, L., Morar, M., Sung, W. W. L., Schwarz, C., Froese, D., Zazula, G., Calmels, F., Debruyne, R., Golding, G. B., Poinar, H. N., & Wright, G. D. (2011). Antibiotic resistance is ancient. Nature, 477(7365), 457-461.
de Figueiredo, C. S., Menezes Silva, S. M. P. d., Abreu, L. S., da Silva, E. F., da Silva, M. S., Cavalcanti de Miranda, G. E., Costa, V. C. d. O., Le Hyaric, M., Siqueira Junior, J. P. d., Barbosa Filho, J. M., & Tavares, J. F. (2019). Dolastane diterpenes from Canistrocarpus cervicornis and their effects in modulation of drug resistance in Staphylococcus aureus. Natural Product Research, 33(22), 3231-3239.
Deak, T., Chen, J., Golden, D. A., Tapia, M. S., Tornai-Lehoczki, J., Viljoen, B. C., Wyder, M. T., & Beuchat, L. R. (2001). Comparison of dichloran 18% glycerol (DG18) agar with general purpose mycological media for enumerating food spoilage yeasts. International Journal of Food Microbiology, 67(1), 49-53.
Degtyareva, N. N., Gong, C., Story, S., Levinson, N. S., Oyelere, A. K., Green, K. D., Garneau-Tsodikova, S., & Arya, D. P. (2017). Antimicrobial activity, AME resistance, and A-Site binding studies of anthraquinone–neomycin conjugates. ACS Infectious Diseases, 3(3), 206-215.
Delcour, A. H. (2009). Outer membrane permeability and antibiotic resistance. Biochimica et Biophysica Acta (BBA) - Proteins and Proteomics, 1794(5), 808-816.
dos Santos Barbosa, C. R., Scherf, J. R., de Freitas, T. S., de Menezes, I. R. A., Pereira, R. L. S., dos Santos, J. F. S., de Jesus, S. S. P., Lopes, T. P., de Sousa Silveira, Z., de Morais Oliveira-Tintino, C. D., Júnior, J. P. S., Coutinho, H. D. M., Tintino, S. R., & da Cunha, F. A. B. (2021). Effect of carvacrol and thymol on NorA efflux pump inhibition in multidrug-resistant (MDR) Staphylococcus aureus strains. Journal of Bioenergetics and Biomembranes, 53(4), 489-498.
dos Santos Silva, M. C., De Farias Silva, C. E., dos Santos, L. M., Medeiros, J. A., Vieira, R. C., de Souza Abud, A. K., Almeida, R. M. R. G., & Tonholo, J. (2022). Alginate lyase produced by filamentous fungus through solid state fermentation using Sargassum from the Brazilian Coast. Waste and Biomass Valorization, 13(6), 2947-2962.
Dumilag, R. V., Lin, S.-M., Zuccarello, G. C., & Kraft, G. T. (2020). The identity of Eucheuma perplexum (Solieriaceae, Gigartinales) and its distinction from Eucheuma serra as exemplified by a proposed new epitype. Phycologia, 59(6), 497-505.
ECDP. (2009). The bacterial challenge: time to react.Retrieved from:
http://ecdc.europa.eu/en/publications/Publications/0909_TER_The_Bacterial_Challenge_Time_to_React.pdf. Accessed July 22 2022.
Edson, R. S., & Terrell, C. L. (1999). The aminoglycosides. Mayo Clinic Proceedings, 74(5), 519-528.
Eicher, T., Cha, H.-j., Seeger, M. A., Brandstätter, L., El-Delik, J., Bohnert, J. A., Kern, W. V., Verrey, F., Grütter, M. G., & Diederichs, K. (2012). Transport of drugs by the multidrug transporter AcrB involves an access and a deep binding pocket that are separated by a switch-loop. Proceedings of the National Academy of Sciences, 109(15), 5687-5692.
Eicher, T., Seeger, M. A., Anselmi, C., Zhou, W., Brandstätter, L., Verrey, F., Diederichs, K., Faraldo-Gómez, J. D., & Pos, K. M. (2014). Coupling of remote alternating-access transport mechanisms for protons and substrates in the multidrug efflux pump AcrB. eLife.
Eichmann, K., & Krause, R. M. (2013). Fred Neufeld and pneumococcal serotypes: foundations for the discovery of the transforming principle. Cellular and Molecular Life Sciences, 70(13), 2225-2236.
Essawi, T., & Srour, M. (2000). Screening of some Palestinian medicinal plants for antibacterial activity. Journal of Ethnopharmacology, 70(3), 343-349.
Ettefagh, K. A., Burns, J. T., Junio, H. A., Kaatz, G. W., & Cech, N. B. (2011). Goldenseal (Hydrastis canadensis L.) extracts synergistically enhance the antibacterial activity of berberine via efflux pump inhibition. Planta Medica, 77(8), 835-840.
Farhadi, F., Khameneh, B., Iranshahi, M., & Iranshahy, M. (2019). Antibacterial activity of flavonoids and their structure–activity relationship: An update review. Phytotherapy Research, 33(1), 13-40.
Farvin, K. H. S., Surendraraj, A., Al-Ghunaim, A., & Al-Yamani, F. (2019). Chemical profile and antioxidant activities of 26 selected species of seaweeds from Kuwait coast. Journal of Applied Phycology, 31(4), 2653-2668.
Fisher, J. B., Badgley, G., & Blyth, E. (2012). Global nutrient limitation in terrestrial vegetation. Global Biogeochemical Cycles, 26(3).
Fleming, A. (1929). On the antibacterial action of cultures of a penicillium, with special reference to their use in the isolation of B. influenzae. British Journal of Experimental Pathology, 10(3), 226.
Frankel, G., David, S., Low, W. W., Seddon, C., Wong, Joshua L. C., & Beis, K. (2023). Plasmids pick a bacterial partner before committing to conjugation. Nucleic Acids Research, 51(17), 8925-8933.
Güven, K. C., Percot, A., & Sezik, E. (2010). Alkaloids in marine algae. Marine Drugs, 8(2), 269-284.
Gervais, P., & Molin, P. (2003). The role of water in solid-state fermentation. Biochemical Engineering Journal, 13(2), 85-101.
Gibbons, S., Oluwatuyi, M., & Kaatz, G. W. (2003). A novel inhibitor of multidrug efflux pumps in Staphylococcus aureus. Journal of Antimicrobial Chemotherapy, 51(1), 13-17.
Giedraitienė, A., Vitkauskienė, A., Naginienė, R., & Pavilonis, A. (2011). Antibiotic resistance mechanisms of clinically important bacteria. Medicina (Kaunas), 47(3), 137-146.
Giraffa, G. (2004). Studying the dynamics of microbial populations during food fermentation. FEMS Microbiology Reviews, 28(2), 251-260.
Gomi, K. (2014). Aspergillus oryzae. In C. A. Batt & M. L. Tortorello (Eds.), Encyclopedia of Food Microbiology (Second Edition) (pp. 92-96). Academic Press.
Gould, I. M., & Bal, A. M. (2013). New antibiotic agents in the pipeline and how they can help overcome microbial resistance. Virulence, 4(2), 185-191.
Gupta, S., Abu-Ghannam, N., & Rajauria, G. (2012). Effect of heating and probiotic fermentation on the phytochemical content and antioxidant potential of edible Irish brown seaweeds. Botanica Marina, 55(5), 527-537.
Hasni, M. H., Ahmad, F. B., & Athoillah, A. Z. (2023). The production of microbial biodiesel from cellulose-derived fungal lipid via consolidated bioprocessing. Environmental Technology & Innovation, 30, 103123.
Heo, S.-J., Park, E.-J., Lee, K.-W., & Jeon, Y.-J. (2005). Antioxidant activities of enzymatic extracts from brown seaweeds. Bioresource Technology, 96(14), 1613-1623.
Holler, J. G., Slotved, H.-C., Mølgaard, P., Olsen, C. E., & Christensen, S. B. (2012). Chalcone inhibitors of the NorA efflux pump in Staphylococcus aureus whole cells and enriched everted membrane vesicles. Bioorganic and Medicinal Chemistry, 20(14), 4514-4521.
Huang, T.-S., Kunin, C. M., Wang, H.-M., Yan, B.-S., Huang, S.-P., Chen, Y.-S., Shin-Jung Lee, S., & Syu, W., Jr. (2013). Inhibition of the Mycobacterium tuberculosis reserpine-sensitive efflux pump augments intracellular concentrations of ciprofloxacin and enhances susceptibility of some clinical isolates. Journal of the Formosan Medical Association, 112(12), 789-794.
Ichishima, E. (2016). Development of enzyme technology for Aspergillus oryzae, A. sojae, and A. luchuensis, the national microorganisms of Japan. Bioscience, Biotechnology, and Biochemistry, 80(9), 1681-1692.
Jin, J., Zhang, J.-Y., Guo, N., Sheng, H., Li, L., Liang, J.-C., Wang, X.-L., Li, Y., Liu, M.-Y., Wu, X.-P., & Yu, L. (2010). Farnesol, a Potential Efflux Pump Inhibitor in Mycobacterium smegmatis. Molecules, 15(11), 7750-7762.
Jones, R. N., Stilwell, M. G., Wilson, M. L., & Mendes, R. E. (2013). Contemporary tetracycline susceptibility testing: doxycycline MIC methods and interpretive criteria (CLSI and EUCAST) performance when testing Gram-positive pathogens. Diagnostic Microbiology and Infectious Disease, 76(1), 69-72.
Judice, J. K., & Pace, J. L. (2003). Semi-synthetic glycopeptide antibacterials. Bioorganic and Medicinal Chemistry Letters, 13(23), 4165-4168.
Klančnik, A., Možina, S. S., & Zhang, Q. (2012). Anti-Campylobacter activities and resistance mechanisms of natural phenolic compounds in Campylobacter. PLoS ONE, 7(12), e51800.
Kresge, N., Simoni, R. D., & Hill, R. L. (2011). The molecular genetics of bacteriophage: the work of Norton Zinder. Journal of Biological Chemistry, 286(25), e4-5.
Kumar, A., Khan, I. A., Koul, S., Koul, J. L., Taneja, S. C., Ali, I., Ali, F., Sharma, S., Mirza, Z. M., & Kumar, M. (2008). Novel structural analogues of piperine as inhibitors of the NorA efflux pump of Staphylococcus aureus. Journal of Antimicrobial Chemotherapy, 61(6), 1270-1276.
Kumar, S., Mukherjee, M. M., & Varela, M. F. (2013). Modulation of Bacterial Multidrug Resistance Efflux Pumps of the Major Facilitator Superfamily. International Journal of Bacteriology, 2013, 204141.
Kumar, S., & Varela, M. F. (2012). Biochemistry of bacterial multidrug efflux pumps. International Journal of Molecular Sciences, 13(4), 4484-4495.
Lahaye, M. (1997). Seaweed dietary fibers structure physicochemical and biological properties relevant to intestinal physiology. Sci. Aliments., 17, 563-564.
Lamut, A., Peterlin Mašič, L., Kikelj, D., & Tomašič, T. (2019). Efflux pump inhibitors of clinically relevant multidrug resistant bacteria. Medicinal Research Reviews, 39(6), 2460-2504.
Lesher, G. Y., Froelich, E. J., Gruett, M. D., Bailey, J. H., & Brundage, R. P. (1962). 1, 8-Naphthyridine derivatives. A new class of chemotherapeutic agents. Journal of Medicinal Chemistry, 5(5), 1063-1065.
Lewis, K. (2013). Platforms for antibiotic discovery. Nature reviews Drug discovery, 12(5), 371-387.
Li, Y., & Ge, X. (2023). Role of Berberine as a Potential Efflux Pump Inhibitor against MdfA from Escherichia coli: In Vitro and In Silico Studies. Microbiology Spectrum, 11(2), e03324-03322.
Liu, L., Heinrich, M., Myers, S., & Dworjanyn, S. A. (2012). Towards a better understanding of medicinal uses of the brown seaweed Sargassum in Traditional Chinese Medicine: A phytochemical and pharmacological review. Journal of Ethnopharmacology, 142(3), 591-619.
Liu, L., Wang, J., Rosenberg, D., Zhao, H., Lengyel, G., & Nadel, D. (2018). Fermented beverage and food storage in 13,000 y-old stone mortars at Raqefet Cave, Israel: Investigating Natufian ritual feasting. Journal of Archaeological Science: Reports, 21, 783-793.
Lomovskaya, O., Warren, M. S., Lee, A., Galazzo, J., Fronko, R., Lee, M., Blais, J., Cho, D., Chamberland, S., Renau, T., Leger, R., Hecker, S., Watkins, W., Hoshino, K., Ishida, H., & Lee, V. J. (2001). Identification and characterization of inhibitors of multidrug resistance efflux pumps in Pseudomonas aeruginosa: novel agents for combination therapy. Antimicrobial Agents and Chemotherapy, 45(1), 105-116.
Lomovskaya, O., Warren, M. S., Lee, A., Galazzo, J., Fronko, R., Lee, M., Blais, J., Cho, D., Chamberland, S., Renau, T., Leger, R., Hecker, S., Watkins, W., Hoshino, K., Ishida, H., & Lee, V. J. (2001). Identification and characterization of inhibitors of multidrug resistance efflux pumps in Pseudomonas aeruginosa: novel agents for combination therapy. Antimicrobial Agents and Chemotherapy, 45(1), 105-116.
Lu, W.-J., Hsu, P.-H., Chang, C.-J., Su, C.-K., Huang, Y.-J., Lin, H.-J., Lai, M., Ooi, G.-X., Dai, J.-Y., & Lin, H.-T. V. (2021). Identified seaweed compound diphenylmethane serves as an efflux pump inhibitor in drug-resistant Escherichia coli. Antibiotics, 10(11), 1378.
Maeda, H., Hosokawa, M., Sashima, T., & Miyashita, K. (2007). Dietary combination of fucoxanthin and fish oil attenuates the weight gain of white adipose tissue and decreases blood glucose in obese diabetic KK-Ay mice. J. of Agricultural and Food Chemistry, 55(19), 7701-7706.
Magiorakos, A. P., Srinivasan, A., Carey, R. B., Carmeli, Y., Falagas, M. E., Giske, C. G., Harbarth, S., Hindler, J. F., Kahlmeter, G., Olsson-Liljequist, B., Paterson, D. L., Rice, L. B., Stelling, J., Struelens, M. J., Vatopoulos, A., Weber, J. T., & Monnet, D. L. (2012). Multidrug-resistant, extensively drug-resistant and pandrug-resistant bacteria: an international expert proposal for interim standard definitions for acquired resistance. Clinical Microbiology and Infection, 18(3), 268-281.
Magro, A. E. A., Silva, L. C., Rasera, G. B., & de Castro, R. J. S. (2019). Solid-state fermentation as an efficient strategy for the biotransformation of lentils: enhancing their antioxidant and antidiabetic potentials. Bioresources and Bioprocessing, 6(1), 38.
Malabarba, A., & Goldstein, B. P. (2005). Origin, structure, and activity in vitro and in vivo of dalbavancin. Journal of Antimicrobial Chemotherapy, 55(suppl_2), ii15-ii20.
Marsh, A. J., Hill, C., Ross, R. P., & Cotter, P. D. (2014). Fermented beverages with health-promoting potential: Past and future perspectives. Trends in Food Science & Technology, 38(2), 113-124.
Matsumoto, Y., Hayama, K., Sakakihara, S., Nishino, K., Noji, H., Iino, R., & Yamaguchi, A. (2011). Evaluation of multidrug efflux pump inhibitors by a new method using microfluidic channels. PLoS ONE, 6(4), e18547.
McGovern, P. E., Zhang, J., Tang, J., Zhang, Z., Hall, G. R., Moreau, R. A., Nuñez, A., Butrym, E. D., Richards, M. P., & Wang, C.-s. (2004). Fermented beverages of pre-and proto-historic China. Proceedings of the National Academy of Sciences, 101(51), 17593-17598.
Mendez-Vilas, A. (2007). Communicating current research and educational topics and trends in applied microbiology.
Menezes-Silva, S., Lira, N. S., Mangueira do Nascimento, Y., Araújo Ramos Meireles, R., da Silva Dias, C., Tavares, J. F., Sobral da Silva, M., Cavalcanti de Miranda, G. E., Barbosa Filho, J. M., & Pinto de Siqueira-Junior, J. (2020). Modulation of drug resistance in Staphylococcus aureus by 132-hydroxy-(132-R/S)-pheophytin isolated from Sargassum polyceratium. Microbial Pathogenesis, 141, 104034.
Michael, C. A., Dominey-Howes, D., & Labbate, M. (2014). The antimicrobial resistance crisis: causes, consequences, and management. Frontiers Public Health, 2, 145.
Mikulášová, M., Chovanová, R., & Vaverková, Š. (2016). Synergism between antibiotics and plant extracts or essential oils with efflux pump inhibitory activity in coping with multidrug-resistant staphylococci. Phytochemistry Reviews, 15(4), 651-662.
Mohammadigheisar, M., Shouldice, V., Sands, J., Lepp, D., Diarra, M., & Kiarie, E. (2020). Growth performance, breast yield, gastrointestinal ecology and plasma biochemical profile in broiler chickens fed multiple doses of a blend of red, brown and green seaweeds. British Poultry Science, 61(5), 590-598.
Mun, S.-H., Joung, D.-K., Kim, Y.-S., Kang, O.-H., Kim, S.-B., Seo, Y.-S., Kim, Y.-C., Lee, D.-S., Shin, D.-W., Kweon, K.-T., & Kwon, D.-Y. (2013). Synergistic antibacterial effect of curcumin against methicillin-resistant Staphylococcus aureus. Phytomedicine, 20(8), 714-718.
Munita, J. M., & Arias, C. A. (2016). Mechanisms of antibiotic resistance. Virulence mechanisms of bacterial pathogens, 481-511.
Muniz, D. F., dos Santos Barbosa, C. R., de Menezes, I. R. A., de Sousa, E. O., Pereira, R. L. S., Júnior, J. T. C., Pereira, P. S., de Matos, Y. M. L. S., da Costa, R. H. S., de Morais Oliveira-Tintino, C. D., Coutinho, H. D. M., Filho, J. M. B., Ribeiro de Sousa, G., Filho, J. R., Siqueira-Junior, J. P., & Tintino, S. R. (2021). In vitro and in silico inhibitory effects of synthetic and natural eugenol derivatives against the NorA efflux pump in Staphylococcus aureus. Food Chemistry, 337, 127776.
Murakami, S., Nakashima, R., Yamashita, E., Matsumoto, T., & Yamaguchi, A. (2006). Crystal structures of a multidrug transporter reveal a functionally rotating mechanism. Nature, 443(7108), 173-179.
Najafpour, G. D. (2007). CHAPTER 10 - Application of Fermentation Processes. In G. D. Najafpour (Ed.), Biochemical Engineering and Biotechnology (pp. 252-262). Elsevier.
Nakashima, R., Sakurai, K., Yamasaki, S., Nishino, K., & Yamaguchi, A. (2011). Structures of the multidrug exporter AcrB reveal a proximal multisite drug-binding pocket. Nature, 480(7378), 565-569.
Nguyen, T. H. T., Nguyen, N. A. T., Nguyen, H. D., Nguyen, T. T. H., Le, M. H., Pham, M. Q., Do, H. N., Hoang, K. C., Michalet, S., Dijoux-Franca, M.-G., & Pham, H. N. (2023). Plant secondary metabolites on efflux-mediated antibiotic resistant Stenotrophomonas maltophilia: potential of herbal-derived efflux pump inhibitors. Antibiotics, 12(2), 421.
Ochsenreither, K., Fischer, C., Neumann, A., & Syldatk, C. (2014). Process characterization and influence of alternative carbon sources and carbon-to-nitrogen ratio on organic acid production by Aspergillus oryzae DSM1863. Applied Microbiology and Biotechnology, 98(12), 5449-5460.
Ohene-Agyei, T., Lea, J. D., & Venter, H. (2012). Mutations in MexB that affect the efflux of antibiotics with cytoplasmic targets. FEMS Microbiology Letters, 333(1), 20-27.
Opperman Timothy, J., Kwasny Steven, M., Kim, H.-S., Nguyen Son, T., Houseweart, C., D'Souza, S., Walker Graham, C., Peet Norton, P., Nikaido, H., & Bowlin Terry, L. (2014). Characterization of a novel pyranopyridine inhibitor of the AcrAB efflux pump of Escherichia coli. Antimicrobial Agents and Chemotherapy, 58(2), 722-733.
Pacios, O., Fernández-García, L., Bleriot, I., Blasco, L., Ambroa, A., López, M., Ortiz-Cartagena, C., González de Aledo, M., Fernández-Cuenca, F., Oteo-Iglesias, J., Pascual, Á., Martínez-Martínez, L., & Tomás, M. (2022). Adaptation of clinical isolates of Klebsiella pneumoniae to the combination of niclosamide with the efflux pump inhibitor phenyl-arginine-β-naphthylamide (PaβN): co-resistance to antimicrobials. Journal of Antimicrobial Chemotherapy, 77(5), 1272-1281.
Paduch, R., Kandefer-Szerszeń, M., Trytek, M., & Fiedurek, J. (2007). Terpenes: substances useful in human healthcare. Archivum Immunologiae et Therapiae Experimentalis, 55, 315-327.
Pagès, J.-M., & Amaral, L. (2009). Mechanisms of drug efflux and strategies to combat them: Challenging the efflux pump of Gram-negative bacteria. Biochimica et Biophysica Acta (BBA) - Proteins and Proteomics, 1794(5), 826-833.
Pal, S., Misra, A., Banerjee, S., & Dam, B. (2020). Adaptation of ethidium bromide fluorescence assay to monitor activity of efflux pumps in bacterial pure cultures or mixed population from environmental samples. Journal of King Saud University - Science, 32(1), 939-945.
Pang, Z., Raudonis, R., Glick, B. R., Lin, T.-J., & Cheng, Z. (2019). Antibiotic resistance in Pseudomonas aeruginosa: mechanisms and alternative therapeutic strategies. Biotechnology Advances, 37(1), 177-192.
Pasteur, L. (1858). Mémoire sur la fermentation appelée lactique.
Pasteur, L. (1860). Note sur la fermentation alcoolique.
Peng, Y., Hu, J., Yang, B., Lin, X.-P., Zhou, X.-F., Yang, X.-W., & Liu, Y. (2015). Chapter 5 - Chemical composition of seaweeds. In Seaweed Sustainability (pp. 79-124).
Pham, T. D. M., Ziora, Z. M., & Blaskovich, M. A. T. (2019). Quinolone antibiotics. Medicinal Chemistry Communications, 10(10), 1719-1739.
Prasch, S., & Bucar, F. (2015). Plant derived inhibitors of bacterial efflux pumps: an update. Phytochemistry Reviews, 14(6), 961-974.
Rampacci, E., Felicetti, T., Cernicchi, G., Stefanetti, V., Sabatini, S., & Passamonti, F. (2023). Inhibition of Staphylococcus pseudintermedius efflux pumps by using Staphylococcus aureus NorA efflux pump inhibitors. Antibiotics, 12(5), 806.
Rangel-Vega, A., Bernstein, L. R., Mandujano Tinoco, E.-A., García-Contreras, S.-J., & García-Contreras, R. (2015). Drug repurposing as an alternative for the treatment of recalcitrant bacterial infections. Frontiers in Microbiology, 6.
Renau, T. E., Léger, R., Flamme, E. M., Sangalang, J., She, M. W., Yen, R., Gannon, C. L., Griffith, D., Chamberland, S., Lomovskaya, O., Hecker, S. J., Lee, V. J., Ohta, T., & Nakayama, K. (1999). Inhibitors of efflux pumps in Pseudomonas aeruginosa potentiate the activity of the fluoroquinolone antibacterial levofloxacin. Journal of Medicinal Chemistry, 42(24), 4928-4931.
Rossolini, G. M., Arena, F., Pecile, P., & Pollini, S. (2014). Update on the antibiotic resistance crisis. Current Opinion in Pharmacology, 18, 56-60.
Sanchez, P., Moreno, E., & Martinez Jose, L. (2005). The biocide triclosan selects Stenotrophomonas maltophilia mutants that overproduce the SmeDEF multidrug efflux pump. Antimicrobial Agents and Chemotherapy, 49(2), 781-782.
Santos, M., Santos, R., Soeiro, P., Silvestre, S., & Ferreira, S. (2023). Resveratrol as an inhibitor of the NorA efflux pump and resistance modulator in Staphylococcus aureus. Antibiotics, 12(7), 1168.
Scocchera, E., & Wright, D. L. (2018). The Antifolates. In J. F. Fisher, S. Mobashery, & M. J. Miller (Eds.), Antibacterials: Volume (pp. 123-149). Springer International Publishing.
Seeger, M. A., Diederichs, K., Eicher, T., Brandstätter, L., Schiefner, A., Verrey, F., & Pos, K. M. (2008). The AcrB efflux pump: conformational cycling and peristalsis lead to multidrug resistance. Curr Drug Targets, 9(9), 729-749.
Seeger, M. A., Schiefner, A., Eicher, T., Verrey, F., Diederichs, K., & Pos, K. M. (2006). Structural asymmetry of AcrB trimer suggests a peristaltic pump mechanism. Science, 313(5791), 1295-1298.
Sengupta, S., Chattopadhyay, M. K., & Grossart, H.-P. (2013). The multifaceted roles of antibiotics and antibiotic resistance in nature. Frontiers in Microbiology, 4, 47.
Sensi, P. (1983). History of the development of rifampin. Reviews of Infectious Diseases, 5, 402-406.
Senthil, A., Mamatha, B. S., Vishwanath, P., Bhat, K. K., & Ravishankar, G. A. (2011). Studies on development and storage stability of instant spice adjunct mix from seaweed (Eucheuma). J Food Sci Technol, 48(6), 712-717.
Shahidi, F. (2008). Bioactives from marine resources. In. ACS Publications.
Shahidi, F., & Alasalvar, C. (2010). Marine oils and other marine nutraceuticals. Handbook of seafood quality, safety and health applications, 444-454.
Sharma, A., Gupta, V. K., & Pathania, R. (2019). Efflux pump inhibitors for bacterial pathogens: From bench to bedside. Indian Journal of Medical Research, 149(2), 129-145.
Sharma, A., Gupta, V. K., & Pathania, R. (2019). Efflux pump inhibitors for bacterial pathogens: From bench to bedside. The Indian journal of medical research, 149(2), 129.
Silva, L., Carrion, L. L., von Groll, A., Costa, S. S., Junqueira, E., Ramos, D. F., Cantos, J., Seus, V. R., Couto, I., Fernandes, L. d. S., Bonacorso, H. G., Martins, M. A. P., Zanatta, N., Viveiros, M., Machado, K. S., & Almeida da Silva, P. E. (2017). In vitro and in silico analysis of the efficiency of tetrahydropyridines as drug efflux inhibitors in Escherichia coli. International Journal of Antimicrobial Agents, 49(3), 308-314.
Silver, S., & Phung, L. T. (1996). Bacterial heavy metal resistance: new surprises. Annual Review of Microbiology, 50(1), 753-789.
Šimat, V., Elabed, N., Kulawik, P., Ceylan, Z., Jamroz, E., Yazgan, H., Čagalj, M., Regenstein, J. M., & Özogul, F. (2020). Recent Advances in Marine-Based Nutraceuticals and Their Health Benefits. Marine Drugs, 18(12), 627.
Slepecky, R. A., & Starmer, W. T. (2009). Phenotypic plasticity in fungi: a review with observations on Aureobasidium pullulans. Mycologia, 101(6), 823-832.
Tenson, T., Lovmar, M., & Ehrenberg, M. (2003). The Mechanism of Action of Macrolides, Lincosamides and Streptogramin B Reveals the Nascent Peptide Exit Path in the Ribosome. Journal of Molecular Biology, 330(5), 1005-1014.
Udrea, A.-M., Dinache, A., Pagès, J.-M., & Pirvulescu, R. A. (2021). Quinazoline Derivatives Designed as Efflux Pump Inhibitors: Molecular Modeling and Spectroscopic Studies. Molecules, 26(8), 2374.
van Bambeke, F., Mingeot-Leclercq, M.-P., Glupczynski, Y., & Tulkens, P. M. (2017). Mechanisms of Action. Infectious Diseases, 1162-1180.
Varela, M. F., Stephen, J., Lekshmi, M., Ojha, M., Wenzel, N., Sanford, L. M., Hernandez, A. J., Parvathi, A., & Kumar, S. H. (2021). Bacterial resistance to antimicrobial agents. Antibiotics, 10(5), 593.
Vargiu, A. V., & Nikaido, H. (2012). Multidrug binding properties of the AcrB efflux pump characterized by molecular dynamics simulations. Proceedings of the National Academy of Sciences, 109(50), 20637-20642.
Veber, D. F., Johnson, S. R., Cheng, H.-Y., Smith, B. R., Ward, K. W., & Kopple, K. D. (2002). Molecular Properties That Influence the Oral Bioavailability of Drug Candidates. Journal of Medicinal Chemistry, 45(12), 2615-2623.
Venter, H., Mowla, R., Ohene-Agyei, T., & Ma, S. (2015). RND-type drug efflux pumps from Gram-negative bacteria: molecular mechanism and inhibition. Frontiers in Microbiology, 6, 377.
Venter, H., Mowla, R., Ohene-Agyei, T., & Ma, S. (2015). RND-type Drug Efflux Pumps from Gram-negative bacteria: Molecular Mechanism and Inhibition. Frontiers in Microbiology, 6.
Viswanathan, V. (2014). Off-label abuse of antibiotics by bacteria. Gut microbes, 5(1), 3-4.
Viveiros, M., Martins, A., Paixão, L., Rodrigues, L., Martins, M., Couto, I., Fähnrich, E., Kern, W. V., & Amaral, L. (2008). Demonstration of intrinsic efflux activity of Escherichia coli K-12 AG100 by an automated ethidium bromide method. International Journal of Antimicrobial Agents, 31(5), 458-462.
Wang, H., Liu, L., Guo, Y. X., Dong, Y. S., Zhang, D. J., & Xiu, Z. L. (2007). Biotransformation of piceid in polygonum cuspidatum to resveratrol by Aspergillus oryzae. Applied Microbiology and Biotechnology, 75(4), 763-768.
Wang, S.-A., Lin, C.-I., Zhang, J., Ushimaru, R., Sasaki, E., & Liu, H.-w. (2020). Studies of lincosamide formation complete the biosynthetic pathway for lincomycin A. Proceedings of the National Academy of Sciences, 117(40), 24794-24801.
Wen, Y.-L., Yan, L.-P., & Chen, C.-S. (2013). Effects of fermentation treatment on antioxidant and antimicrobial activities of four common Chinese herbal medicinal residues by Aspergillus oryzae. Journal of Food and Drug Analysis, 21(2), 219-226.
WHO. (2014). Antimicrobial resistance: global report on surveillance. http://apps.who.int/iris/bitstream/10665/112642/1/9789241564748_eng.pdf. Accessed 17 May 2018.
Yamasaki, S., Koga, N., Zwama, M., Sakurai, K., Nakashima, R., Yamaguchi, A., & Nishino, K. (2022). Spatial characteristics of the efflux pump MexB determine inhibitor binding. Antimicrobial Agents and Chemotherapy, 66(11), e00672-00622.
Yan, Y.-H., Li, G., & Li, G.-B. (2020). Principles and current strategies targeting metallo-β-lactamase mediated antibacterial resistance. Medicinal Research Reviews, 40(5), 1558-1592.
Yim, G., Thaker, M. N., Koteva, K., & Wright, G. (2014). Glycopeptide antibiotic biosynthesis. The Journal of Antibiotics, 67(1), 31-41.
Yoshida, K.-i., Nakayama, K., Ohtsuka, M., Kuru, N., Yokomizo, Y., Sakamoto, A., Takemura, M., Hoshino, K., Kanda, H., Nitanai, H., Namba, K., Yoshida, K., Imamura, Y., Zhang, J. Z., Lee, V. J., & Watkins, W. J. (2007). MexAB-OprM specific efflux pump inhibitors in Pseudomonas aeruginosa. Part 7: Highly soluble and in vivo active quaternary ammonium analogue D13-9001, a potential preclinical candidate. Bioorganic and Medicinal Chemistry, 15(22), 7087-7097.