IntroductionNowadays, it has been g

IntroductionNowadays, it has been given considerable emphasis to theenvironmental impacts caused by chemical surfactants due totheir high toxicity and non-biodegradable properties [1]. Biosur-factants are natural surfactants produced extracellulary or as partof the cell membrane by bacteria, yeasts or fungi from differ-ent substrates, including sugars, oils, alkanes [2]. Biosurfactantshave some advantages over petroleum-based surfactants, such asbiodegradability, production from renewable substrates, low toxic-ity, biocompatibility, digestibility, diversity for chemical structureand properties, effectiveness even at extreme conditions of tem-perature, pH and salinity [3]. Some desirable characteristics of anefficient biosurfactant are related to the reduction of the surfacetension of water to 27 mN m−1, reduction of the interfacial tensionon water/hydrocarbon systems and a low critical micellar con-centration [4,5]. Due to these advantages, biosurfactants are good candidates to be used in environmental applications and in dif-ferent industries such as petroleum, food production, chemistry,cosmetics and pharmaceutics [6,7].Environmental risks involved in oil spills in association withheavy metals have increased and few technologies are able todeal with the effects of both contaminants simultaneously. Biosur-factants may be used for the removal of both organic and metalcontaminants and present similar behavior to increase their solu-bility in water, which facilitates their removal by biodegradationor flushing.Among different biosurfactants and producing microorganisms,the production of lipopeptide biosurfactants, mostly produced byBacillus sp., is highlighted due to its considerable efficiency andcommercial interest [1]. The most known lipopeptide biosurfac-tant are divided in three groups (surfactins, iturins and fengycins),and each group consists on isoforms and homologous series. Sur-factin is one of the most powerful biosurfactants and it has gainedattention for industrial application, since it can lower the surfacetension of water from 72 to 27 mN m−1at low concentrations [8],and also due to its antimicrobial, antiviral and antitumor activities[Surfactin is a mixture of isoforms and homologous seriespresenting some differences in their physicochemical propertiesmainly caused by variations in the chain length (C12–C16) andbranching of its hydroxy fatty acid component as well as replace-ments of the amino acid components on the peptide ring [9].These variations might be genetically determined, depend on thestrain, or even on the operational conditions used for biosurfac-tant production [9]. The differences on physicochemical propertieson homologues series and isoforms of biosurfactants might affectthe application and effectiveness of these biomolecules, then beingnecessary to evaluate its functional properties, toxicity and suit-ability for industrial application [10].In this context, this study aimed to evaluate the production ofbiosurfactant by a new strain of Bacillus subtilis ICA56, grown on lowcost substrates, analyze its functional properties under differentabiotic variables, and test its potential to remove hydrocarbons andmetals.