Department of Physiology and Pharmacology, Universidade Federal de Santa Maria, Santa Maria, RS, Brazil.
Department of Physiology and Pharmacology, Universidade Federal de Santa Maria, Santa Maria, RS, Brazil.
Microb Pathog. 2020 Apr;141:103989. doi: 10.1016/j.micpath.2020.103989. Epub 2020 Jan 23.
Rampant and uncontrolled use of antibiotics is a major concern for aquaculture; the practice foments the emergence of resistant strains of Streptococcus agalactiae, among other negative impacts. Constituents of plant essential oils such as nerolidol are being considered as replacements for synthetic drugs to support fish nutrition and health. There is evidence to suggest that nanotechnology may enhance the efficacy of natural bioactive compounds; this is a substantial advance for the development and sustainability of aquaculture. Against the backdrop of this evidence, we aimed determine whether dietary supplementation with free nerolidol and nerolidol-loaded nanospheres would exert bactericidal effects against S. agalactiae, as well as prevent S. agalactiae-induced brain oxidative damage. In Experiment I, we measured the antimicrobial properties of dietary supplementation of nerolidol and nerolidol nanosphere in terms of mortality, longevity and relative percent survival. Fish infected with S. agalactiae fed 0.5 and 1.0 mL nerolidol nanospheres kg/diet demonstrated lower mortality and higher relative percent survival than the control group, while longevity was higher in all infected plus supplementation groups. Experiment II showed significantly lower microbial loads in brains of fish infected with S. agalactiae that were fed 1.0 mL nerolidol nanospheres kg/diet than in the control group. Brain nerolidol levels were significantly higher in uninfected as well as infected fish supplemented with nerolidol nanospheres than in fish supplemented with free nerolidol. Finally, brain reactive oxygen species and lipid peroxidation levels were higher in infected fish supplemented with basal diet compared to uninfected fish and supplemented with basal diet, and the supplementation with 1.0 mL/kg nerolidol nanospheres prevented this augmentation caused by infection. These data suggest that dietary supplementation with nerolidol nanospheres (1.0 mL/kg diet) has potent bactericidal effects in terms of augmentation of fish longevity and survival, and reduction of brain microbial loads. Also, S. agalactiae-induced brain oxidative damage that contributed to disease pathogenesis, and the dietary supplementation with nerolidol nanospheres (1.0 mL/kg diet) prevented this alteration. In summary, nanotechnology is a compelling approach to enhancing the efficacy of nerolidol, giving rise to reduction of S. agalactiae loads in fish brains.
抗生素的滥用是水产养殖的主要关注点;这种做法助长了无乳链球菌等耐药菌株的出现,以及其他负面影响。植物精油的成分,如橙花叔醇,正被考虑作为合成药物的替代品,以支持鱼类的营养和健康。有证据表明,纳米技术可以提高天然生物活性化合物的功效;这是水产养殖发展和可持续性的重大进步。有鉴于此,我们旨在确定自由橙花叔醇和橙花叔醇负载纳米球的饮食补充是否会对无乳链球菌产生杀菌作用,并防止无乳链球菌引起的脑氧化损伤。在实验 I 中,我们根据死亡率、寿命和相对存活率来衡量饮食补充橙花叔醇和橙花叔醇纳米球的抗菌特性。感染无乳链球菌并喂食 0.5 和 1.0 mL 橙花叔醇纳米球/千克饲料的鱼的死亡率较低,相对存活率较高,而所有感染加补充组的寿命都较高。实验 II 表明,感染无乳链球菌的鱼的大脑中微生物负荷显著低于对照组。与未感染且补充自由橙花叔醇的鱼相比,未感染和感染的鱼补充橙花叔醇纳米球后大脑中的橙花叔醇水平显著升高。与未感染且补充基础饲料的鱼相比,感染鱼补充基础饲料时大脑中的活性氧和脂质过氧化水平较高,而补充 1.0 mL/kg 橙花叔醇纳米球可防止这种由感染引起的增加。这些数据表明,饮食补充橙花叔醇纳米球(1.0 mL/kg 饲料)具有增强鱼寿命和存活率、减少大脑微生物负荷的杀菌作用。此外,无乳链球菌诱导的脑氧化损伤导致疾病发病机制,而饮食补充橙花叔醇纳米球(1.0 mL/kg 饲料)可防止这种变化。总之,纳米技术是增强橙花叔醇功效的一种有吸引力的方法,可以减少鱼脑中的无乳链球菌负荷。
