Addition of zinc, manganese, and iron to growth media triggers antibiotic production in bacterial isolates fron the lower atmosphere

Quinn Washburn, S. Spradlin, C. Weber
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引用次数: 0

Abstract

antibiotics often point to Actinomycetales (Bérdy, 2012; Goodfellow & Fiedler, 2010). Goodfellow & Fiedler (2010) stated that by using selective techniques, such as sampling from understudied and extreme environments, novel Actinobacteria may be discovered. One such environment, is the lower atmosphere (Weber and Werth, 2015), which is defined by as the first 20km above ground level (Womack, Bohannan, & Green 2010). A multitude of both culture-dependent and culture-independent studies demonstrate that Actinobacteria are an omnipresent component of the aerial environment (Bowers et al., 2011; Fahlgren, Hagström, Nilsson, & Zweifel, 2010; Polymenakou, 2012; Shaffer & Lighthart, 1997; Weber & Werth, 2015). The lower atmosphere has several distinct advantages in the search for novel Actinomycetales. The lower atmosphere is a highly variable environment (Fahlgren et al., 2010) with dramatically oscillating temperatures (-56°C to 15°C), low relative humidity and high levels of ultraviolet radiation (Womack, Bohannan, & Green, 2010). These conditions may select for Actinomycetales over faster-growing bacterial taxa, such as many Proteobacteria (Weber & Werth, 2015). Exploring the lower atmosphere, given its potential to harbor antibiotic-producing bacteria, with selective cultivation methods may lead to the discovery of novel species and antibiotics. While not as commonly studied for their antibiotic-producing capabilities, Bacillus is another genus of bacteria that contains antibiotic-producing members and is commonly found in the lower atmosphere (Athukorala, Dilantha Fernando, & Rashid, 2009; Fahlgren et al., 2010; Shaffer & Lighthart, 1997). Another approach to discover novel antibiotic compounds is to place a single organism under a wide array of culture conditions INTRODUCTION According to the World Health Organization (2015), pathogens are becoming more antibiotic-resistant than ever before, which is a problem caused and exacerbated by the overuse and misuse of existing antibiotics. As a result, there is a desperate need for novel antibiotics, but the approval rate of clinical antibiotics continues to decline (Donadio, Maffioli, Monciardini, Sosio, & Jabes, 2010). The order Actinomycetales within the phylum Actinobacteria, includes the genus Streptomyces, which produces two-thirds of known antibiotics (Barka et al., 2016; Watve, Tickoo, Jog, & Bhole, 2001). This genus is predicted to produce 150,000 to almost 300,000 antimicrobial compounds still awaiting discovery (Watve et al., 2001). Therefore, predictions about the next source of novel Addition of Zinc, Manganese, and Iron to Growth Media Triggers Antibiotic Production in Bacterial Isolates From the Lower Atmosphere
在生长培养基中添加锌、锰和铁会引发低层大气中细菌分离株产生抗生素
抗生素通常指向放线菌(Bérdy,2012;Goodfellow和Fiedler,2010)。Goodfellow和Fiedler(2010)指出,通过使用选择性技术,例如从研究不足和极端环境中采样,可以发现新的放线菌。一种这样的环境是较低的大气层(Weber和Werth,2015),它被定义为地面以上20公里的第一层(Womack,Bohannan,&Green,2010)。大量依赖培养物和非依赖培养物的研究表明,放线菌是空中环境中无处不在的组成部分(Bowers等人,2011;Fahlgren、Hagström、Nilsson和Zweifel,2010年;Polymnakou,2012年;Shaffer和Lighthart,1997年;Weber和Werth,2015年)。在寻找新型放线菌方面,较低的大气层有几个明显的优势。低层大气是一个高度可变的环境(Fahlgren等人,2010),具有显著的振荡温度(-56°C至15°C)、低相对湿度和高水平的紫外线辐射(Womack,Bohannan,&Green,2010)。这些条件可能会选择放线菌纲,而不是生长较快的细菌类群,如许多变形杆菌(Weber&Werth,2015)。鉴于低层大气有可能携带产生抗生素的细菌,通过选择性培养方法探索低层大气可能会发现新的物种和抗生素。虽然芽孢杆菌的抗生素生产能力没有得到普遍研究,但它是另一个含有抗生素生产成员的细菌属,通常在低层大气中发现(Athukorala,Dilandha Fernando,&Rashid,2009;Fahlgren等人,2010年;Shaffer和Lighthart,1997年)。发现新型抗生素化合物的另一种方法是将单个生物体置于广泛的培养条件下。引言根据世界卫生组织(2015)的说法,病原体比以往任何时候都更具抗生素耐药性,这是一个由现有抗生素的过度使用和误用引起并加剧的问题。因此,人们迫切需要新型抗生素,但临床抗生素的批准率持续下降(Donadio,Maffioli,Monciardini,Sosio,&Jabes,2010)。放线菌门中的放线菌目包括链霉菌属,它产生三分之二的已知抗生素(Barka等人,2016;Watve、Tickoo、Jog和Bhole,2001年)。据预测,该属将产生150000至近300000种仍有待发现的抗菌化合物(Watve等人,2001)。因此,对生长介质中新添加锌、锰和铁的下一个来源的预测触发了低层大气细菌分离物中抗生素的产生
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