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Rice husk, one of the main side products in the rice production, and its sustainable management represent a challenge in many countries. Herein, we describe the use of this abundant agricultural bio‐waste as feedstock for the preparation of silver‐containing carbon/silica nano composites with antimicrobial properties. The synthesis was performed using a fast and cheap methodology consisting of wet impregnation followed by pyrolysis, yielding C/SiO2 composite materials doped with varying amounts of silver from 28 to 0.001 wt %. The materials were fully characterized and their antimicrobial activity against ESKAPE pathogens, namely E. faecium, S. aureus, K. pneumoniae, A. baumannii, P. aeruginosa, and E. coli, and the pathogenic yeast C. albicans was investigated. Sensitivities of these strains against the prepared materials were demonstrated, even with exceptional low amounts of 0.015 m% silver. Hence, we report a straightforward method for the synthesis of antimicrobial agents from abundant sources which addresses urgent questions like bio‐waste valorization and affordable alternatives to increasingly fewer effective antibiotics.
The discovery of antibiotics around one century ago was a milestone for medicine. However, despite the warning of Alexander Fleming in 1945, antibiotics were used poorly, resulting in many antibiotic-resistant pathogens. Patients infected with resistant pathogens need to get treated with additional antibiotics or, as a last resort, trust completely on their immune system. This causes 700,000 deaths per year. Most clinically used antibiotics have been derived from soil microorganisms, while other niches stayed unexplored. Exploring new niches inhabiting antibiotic-producing microorganisms may result in novel antibiotics. Furthermore, expanding the search from frequently investigated soluble metabolites to volatiles may open up numerous compounds as potential future antibiotics. This thesis is about the search for antimicrobial volatiles produced (among others) by microorganisms from social spider ecosystems, a niche that was little explored until now.
Volatiles are characterized by their high vapor pressure at ambient temperatures, allowing them to distribute fast in both the gas and water phase. They can spread quickly even in complex ecosystems using the air and potentially fulfill functions like communication and antimicrobial defense. Especially, volatiles with antimicrobial activities caught the attention of many scientists because of their potential role in pathogen defense, as we have reviewed (Article I). Volatiles are usually produced in the primary metabolism and belong to diverse chemical classes, like hydrocarbons, aromates, alcohols, aldehydes, acids, esters, amides, and thiols. Their antimicrobial spectrum ranges from antifungal, to antibacterial, anti-oomycete, and even broad-spectrum activity. Volatiles are ubiquitously produced. Especially Bacillus and Streptomyces species are often reported to produce antimicrobial volatiles. Knowledge about antimicrobial volatiles – for example, details about their modes of action – is lacking yet, but these compounds may help to overcome the antimicrobial resistance crisis in the future. Volatiles could be used in medicine and agriculture, either alone or in combination with traditional antibiotics, opening new strategies against antimicrobial resistance.
A promising source of (volatile) antimicrobials is the ecosystem of social arthropods. Due to their lifestyle in dense colonies, they likely spread pathogens between individuals, making antimicrobial defense crucial. Since the presence of antimicrobial volatiles was reported in social insect ecosystems, we investigated the unexplored volatilome of the Namibian social spider Stegodyphus dumicola (Articles II and III). In the first study, we analyzed the in situ volatilomes of the spiders’ nest, web, and bodies using GC/Q-TOF and revealed that more than 40 % of the tentatively identified volatiles were already known for their antimicrobial activities (Article II). We proved the antimicrobial activity of five pure compounds found in the samples, among others against the suggested spider pathogen Bacillus thuringiensis. These results indicate the potential role of antimicrobial volatiles for pathogen defense and could ultimately help explain the spiders’ ecological success.
Volatiles from the spider volatilome can originate from various sources, including microorganisms, surrounding plants, the spiders themselves, the spiders’ prey, so we analyzed the volatilomes of microbial nest members in a second study. The microbial nest members we selected for this were the bacteria Massilia sp. IC2-278, Massilia sp. IC2-477, Sphingomonas sp. IC-11, and Streptomyces sp. IC-207, and the fungus Aureobasidium sp. CE_32 (Article III). Several volatilomes showed antibacterial and/or antifungal activities against two suggested spider pathogens. The subsequent volatilome analyses using GC/Q-TOF revealed the presence of many volatiles that have already been described as antimicrobials. Five pure volatiles were tested against two suggested spider pathogens, revealing all volatiles as antibacterial, antifungal, or both. These results support the potential role of antimicrobial volatiles in social spider pathogen defense and indicate microbial nest members as the origin of (novel) antimicrobial volatiles.
Together, the articles that constitute this thesis highlight the antimicrobial power of volatiles (Article I), indicates the volatilome of the ecosystem of S. dumicola as a potential pathogen defense (Article II), and finally reveal the spider nest microbiome as a source for antimicrobial volatiles (Article III). This knowledge not only adds to the understanding of social spider ecosystems (and likely other social arthropod ecosystems) but also has the potential to open a novel source for antimicrobial compounds that may help to counter the antimicrobial resistance crisis.
We are currently facing an antimicrobial resistance crisis, which means that a lot of bacterial pathogens have developed resistance to common antibiotics. Hence, novel and innovative solutions are urgently needed to combat resistant human pathogens. A new source of antimicrobial compounds could be bacterial volatiles. Volatiles are ubiquitous produced, chemically divers and playing essential roles in intra- and interspecies interactions like communication and antimicrobial defense. In the last years, an increasing number of studies showed bioactivities of bacterial volatiles, including antibacterial, antifungal and anti-oomycete activities, indicating bacterial volatiles as an exciting source for novel antimicrobial compounds. In this review we introduce the chemical diversity of bacterial volatiles, their antimicrobial activities and methods for testing this activity. Concluding, we discuss the possibility of using antimicrobial volatiles to antagonize the antimicrobial resistance crisis.
Social arthropods such as termites, ants, and bees are among others the most successful animal groups on earth. However, social arthropods face an elevated risk of infections due to the dense colony structure, which facilitates pathogen transmission. An interesting hypothesis is that social arthropods are protected by chemical compounds produced by the arthropods themselves, microbial symbionts, or plants they associate with. Stegodyphus dumicola is an African social spider species, inhabiting communal silk nests. Because of the complex three-dimensional structure of the spider nest antimicrobial volatile organic compounds (VOCs) are a promising protection against pathogens, because of their ability to diffuse through air-filled pores. We analyzed the volatilomes of S. dumicola, their nests, and capture webs in three locations in Namibia and assessed their antimicrobial potential. Volatilomes were collected using polydimethylsiloxane (PDMS) tubes and analyzed using GC/Q-TOF. We showed the presence of 199 VOCs and tentatively identified 53 VOCs. More than 40% of the tentatively identified VOCs are known for their antimicrobial activity. Here, six VOCs were confirmed by analyzing pure compounds namely acetophenone, 1,3-benzothiazole, 1-decanal, 2-decanone, 1-tetradecene, and docosane and for five of these compounds the antimicrobial activity were proven. The nest and web volatilomes had many VOCs in common, whereas the spider volatilomes were more differentiated. Clear differences were identified between the volatilomes from the different sampling sites which is likely justified by differences in the microbiomes of the spiders and nests, the plants, and the different climatic conditions. The results indicate the potential relevance of the volatilomes for the ecological success of S. dumicola.