1 INTRODUCTION

Mining is one of the most important economic activities in Brazil (Penna, Martins & Silveira, 2022), where the state of Minas Gerais (MG) is a pioneer in this sector, being responsible for about 50 % of the value of mining production in the country (Passos, Coelho & Dias, 2017). During the mining and processing process, a large amount of tailings is generated (Lopes, Rodovalho & Hajj, 2022; Almeida et al., 2021; Mendes et al., 2019), which are stored in containment dams. However, due to natural events (such as earthquakes) or planning failures in construction or maintenance, dams are liable to collapse, releasing their waste into the aquatic environment (IBRAM, 2016). This becomes worrying since these wastes may contain toxic chemical elements, especially heavy metals (Paes et al., 2023).

The state of Minas Gerais is marked by tragic events related to mining activity and by the year 2022, eight mining dam collapses had occurred (Lacaz, Porto & Pinheiro, 2017; Barbosa & Amaral, 2022). Two of the most recent disasters, the collapse of the Fundão dam (Mariana-MG) on November 5, 2015 and the Córrego do Feijão Mine dam (Brumadinho-MG) on January 25, 2019, occurred within a short period of time between them, had a huge social and environmental impact, and point to the need for dam safety surveillance (Milanez, Ali & Oliveira, 2021).

The collapse of the Fundão dam caused the release of about 34 million cubic meters (m3 ) of mining tailings into the Doce River basin (IBAMA, 2015), while after the failure of the Córrego do Feijão Mine dam, approximately 11.7 million m3 of mining tailings were released into the Paraobeba River, in the São Francisco River basin (Porsani, Jesus & Stangari, 2019). After both disasters, an increase in the concentration of several heavy metals was reported along the waters of the affected rivers, especially Iron (Fe), Manganese (Mn), Aluminum (Al), and Cadmium (Cd) (IGAM, 2016; IGAM, 2019; Cionek, Alves, Tófoli, Rodrigues-Filho & Dias, 2019; Macêdo et al., 2020).

Heavy metals are highly toxic even at low concentrations and are highly recalcitrant in the environment (Guo et al., 2022). In humans, these elements may be associated with various health problems, ranging from poisoning to more serious cases related to carcinogenesis and death (Oliveira, Kuno, Nascimento & Gouveia, 2021). At the environmental level, in addition to the contamination of water, soil, and aquatic organisms (Husejnovic et al., 2018; Gwimbi, Kotelo & Selimo, 2020), these elements can promote structural changes, death, and increased expression of resistance genes to metals in microbial communities (Salam, Obayori, Ilori & Amund, 2020). In addition, they are associated with the evolution and dissemination of antimicrobial resistance (AMR), considered a serious public health problem (Stepanauskas et al., 2006; Bednorz et al. 2013; Alawi, Torrijos & Walsh, 2022; Janotto, Luciano & Evangelista, 2022).

AMR refers to the ability of microorganisms (bacteria, viruses, fungi and parasites) to change after exposure to antimicrobials, resulting in loss of activity. In this way, there is a limitation of the options for treating infections and the dissemination of resistant bacteria can be favored (WHO, 2021). Although antimicrobial resistance genes occur naturally in the environment, in low amounts, contaminants such as heavy metals are able to increase them (Edet, Bassey & Joseph, 2023). Heavy metals can enrich determinants of resistance genes through co-selection mechanisms, due to the fact that resistance to antimicrobials and heavy metals share the same or similar genetic mechanisms (Baker-Austin, Wright, Stepanauskas & McArthur, 2006; Seiler & Berendonk, 2012). Several studies have shown that antimicrobial-resistant bacteria recovered from polluted environments were also resistant to heavy metals, raising questions about the possibility of inducing antimicrobial resistance by metals present as environmental contaminants (Thomas et al., 2020; Hahn, Bahlis, Basso & Van der Sand, 2015; Matyar et al., 2014).

In view of the above, this study aims to analyze existing scientific evidence to date that describes the relationship between bacteria recovered from sites affected by mining tailings resulting from the collapse of the aforementioned dams, and the development of antimicrobial resistance.

2 METHODOLOGY

2.1 Study Design

This study is an integrative literature review, a method that provides the synthesis of various empirical or theoretical research already published, in order to provide a broader understanding of a particular area of study (Lima et al., 2023).

In this review, studies were approached that associate the presence of heavy metals as environmental contaminants, released after the collapse of mining dams, and the development of antimicrobial resistance, analyzed in bacteria recovered from these sites. To this end, the guiding question of the study was: "Can the presence of heavy metals resulting from mining tailings released after dam failures in Brazil favor antimicrobial resistance?"

From the guiding question, the "PICO" was established, with the study population (Population) being: bacteria recovered from environments contaminated by the collapse of the Fundão and Córrego do Feijão Mine dams; Intervention: exposure to heavy metals resulting from mining tailings; the control group (Control): absence of exposure to metals; and Outcome: the development of antimicrobial resistance.

2.2 Search Strategy

Four databases were used to search for studies (PubMed, Virtual Health Library (VHL), Science Direct, and Web of Science), which was performed for the period from October 13, 2022 to February 2, 2023. To carry out the search, the descriptors in English "antimicrobial resistance", "heavy metal", "dam", and "Brazil", and also in Portuguese "resistência antimicrobiana", "metal pesado", "barragem" and "Brasil" were used, combined together with the Boolean operator "AND" ("antimicrobial resistance" AND "heavy metal" AND "dam" AND "Brazil") ("resistência antimicrobiana" AND "metal pesado" AND "barragem" AND "Brasil").

2.3 Selection of the Studies

After conducting searches in the aforementioned databases, duplicate publications were excluded. Next, the titles and abstracts were read, excluding articles that did not fit the theme of this review, and the remaining articles were read in full. In addition, to locate articles that had not been found in the databases used, a search was carried out in the reference lists of the selected articles.

2.4 Eligibility Criteria

Articles published in English, Portuguese, and Spanish and that answered the guiding question of the study were considered eligible. Book chapters, literature reviews, dissertations, theses, monographs, books, editorials, manuals, news, reports and comments were excluded.

2.5 Data Collection

After reading the articles in full that met the inclusion criteria, information extracted from them was recorded in Table 1, which addressed detailed information about all the studies included in this review (author, year, objective of the study, analyzed sample, methodology used, control group, main results, and limitations of the study). All steps were performed blindly and independently by three of the authors of this review.

3 RESULTS

A total of 434 articles were found in the analyzed databases, of which 22 were excluded because they were in duplicate (n=412). Of the remaining 412 articles, 384 were excluded by title and/or abstract and subsequently 28 articles were selected by title and/or abstract and read in full. After reading, 23 articles were excluded according to the eligibility criteria, and one article was found by searching the references of selected articles, with a total of six articles being included at the end of this review. Figure 1 presents the methodology used in the selection of articles included in this review.

All six studies were carried out in Brazil, but some of them with the collaboration of other countries such as Chile, Costa Rica, and the United States.

Table 1 presents detailed information on the selected articles. Four studies (66. 7%) referred to the Fundão dam and two (33.3 %) referred to the Córrego do Feijão Mine dam.

In general, all six studies presented in this review suggest that environmental contamination by heavy metals resulting from mining tailings released after the collapse of the Fundão and the Córrego do Feijão Mine dams favored the appearance of antimicrobial resistance genes (ARGs), that is, at least the development of bacterial resistance may be related to the pressure caused by heavy metals.

In relation to the studies referring to the Fundão dam, Suhadolnik et al. (2022) analyzed sediment samples from rivers belonging to the Doce River basin, quantified the metals present in these samples by optical emission spectrometry, extracted the DNA and, using bioinformatics techniques, performed the prediction of ARGs. The concentrations of metals were within the stipulated by the National Council for the Environment (Conselho Nacional do Meio Ambiente - CONAMA) with the exception of Chromium (Cr) and Cd, and the concentration of Fe, Mn, Mg, and Cr was higher in the rivers affected by the disaster. Genomic analysis resulted in 684 different resistance genes, covering all classical resistance mechanisms and classes of clinically relevant antimicrobials, including last-line compounds for the treatment of infections caused by multidrugresistant bacteria, 38 % of which were exclusive to impacted rivers. The affected rivers had a higher proportion of unique ARGs compared to the reference river, i.e. they were more similar. Furthermore, critical antibiotic resistance genes (ARGs) such as mcr and ereA2 were significantly more common in the disturbed microbiomes. The metals Magnesium (Mg), Fe, and Copper (Cu) were those that most correlated with antimicrobial resistance, with a strong interaction between Cu and genes for resistance to β-lactams, aminoglycosides, and macrolides being reported (Table 1).

Vasconcelos et al. (2022) analyzed soil samples collected near the Doce River. Initially, the samples were placed on tryptone soy agar with nystatin and Mn, and later, susceptibility tests for β-lactams, aminoglycosides, tetracycline, quinolones, DNA extraction, and PCR were carried out. A total of 21 strains were found, 18 of which were Bacillus and three Mucilaginibacter, all with antimicrobial resistance and resistance to metals. Among them, the strain Mucilaginibacter sp. 21p was that which most demonstrated resistance to metals and antimicrobials. Although there were no antimicrobial residues generating selective pressure in the environment, the bacterial community was exposed to heavy metals and the development of antimicrobial resistance was attributed to the occurrence of cross-resistance with these heavy metals (Table 1).

Gaeta et al. (2022) retrieved water samples from eight different locations to investigate the occurrence of clinically important bacteria. The samples were placed on MacConkey agar plates with ceftriaxone, the strains were identified by mass spectrometry and susceptibility tests, and determination of the resistance mechanism by the double disk synergy test, as well as DNA extraction were performed. Environmental Escherichia colistrains co-hosting the clinically relevant bla CTX-M-2 ESBL (extended spectrum beta-lactamase) gene and operon mer genes that confer mercury tolerance were found after the disaster. These bacteria were also resistant to a number of antimicrobials such as ceftriaxone, cefotaxime, cefepime, trimethoprim/sulfamethoxazole, amikacin, gentamicin and tetracycline) (Table 1).

Gaeta et al. (2020) analyzed the microbiota of the nasopharynx, rumen, and rectum of 16 dairy cows belonging to a farm where the water consumed by the animals was affected by mining waste. Although the animals did not demonstrate clinical manifestations, by molecular approach, about 200 different genera of bacteria were found in the experimental group cows compared to the control group. In addition, on the farm that had water impacted by heavy metals, a higher prevalence and abundance of antimicrobial resistance genes was reported, with a high frequency of active efflux mechanisms. Differences in the diversity of the aquatic microbiota suggest that exposure to water contaminated with heavy metals can interfere with the microbiota of dairy cattle, and consequently, interfere with animal productivity (Table 1).

Regarding the dam at the Córrego do Feijão Mine, Thompson et al. (2023) analyzed samples collected one week (February/2019) and four months (May/2019) after the disaster, in eight locations along the Paraopeba River. Total DNA was extracted from the samples and subsequently quantified, and metagenomic analyzes were performed. In addition, bacteria present in the water samples were isolated and resistance was tested for a series of antimicrobials. The most abundant phyla in the studied areas after the disaster were Proteobacteria (29–73 %), Firmicutes (0–54 %), Bacteroidetes (0–50 %), Actinobacteria (4–22 %) and Cyanobacteria (0–23 %), with the predominance of Firmicutes, mainly Bacillus (71 %) and Proteobacteria, mainly Acinetobacter (28 %), and directly implies pollution by heavy metal contamination.

In addition, Pseudomonas (n = 26), Enterobacter (n = 26), Raoultella (n = 7), and Klebsiella (n = 5) bacteria were the most abundant in the samples, these bacteria are reported to be multiresistant to numerous antibiotics. Resistance analyzes showed that all isolates were resistant to at least one type of antibiotic, the main ones being: ampicillin, ampicillin/sulbactam, amikacin and meropenem, but also ceftriaxone, cefuroxime, cefepime, ciprofloxacin and gentamicin. This increase in resistance suggests a possible influence of tailings sludge on the spread of antibiotic resistance in the Paraopeba River (Table 1).

The study by Furlan et al. (2020) analyzed 30 samples, including soil, sediment, and water from the Paraopeba River, affected by mining tailings. The physical-chemical conditions of the water were determined, the DNA of the samples was extracted, and the antimicrobial resistance genes researched by PCR. Samples from affected sites showed high turbidity, in addition to values of Mn, Al, Fe, and Cu above those allowed by law (CONAMA 357/05) for water bodies, and high concentrations of Fe, Al, Cu, Mn, and Cd for soils and sediments. The averages of ARGs found in unaffected sites and in affected sites were 29 and 45, respectively, being detected 1.55 times more in sites affected by the disaster, with ARGs being associated with resistance to β-lactams, quinolones, aminoglycosides, sulfonamides, phenicols and glycopeptides the most increased. After the disaster, resistance genes were detected for important classes of antimicrobials such as: βlactams (blaCMY, blaSHV, blaTEM, blaCTX-M-Gp1, blaCTX-M-Gp9), quinolones (qepA, oqxA, oqxB, qnrB, qnrS), aminoglycosides (aadA, aac(6')-lb, aph(3')-la, aph(3')-VI), tetracyclines (tet(B), tet(C), tet(D)), phenicols (floR, cmla), sulfonamides (sul1, sul2, sul3), glycopeptides (vanC1, vanC2/3), and macrolides (erma, ermB, ermC, mefAE). It is noteworthy that the presence of heavy metals was responsible for greater selective pressure, favoring the emergence of bacteria with a multi-drug resistant (MDR) phenotype (Table 1).

4 DISCUSSION

The evolution and spread of antimicrobial resistance may be associated with factors that are independent of the use of antimicrobials in humans and animals, such as environmental pollution resulting from human activities. In this context, contamination by heavy metals stands out as one of the main selectors of organisms resistant to antimicrobials (Stepanauskas et al., 2006; Bednorz et al., 2013), being important in the maintenance and proliferation of AMR (Wales & Davies, 2015; Lin et al., 2017).

Heavy metals are associated with the spread of AMR since phenotypes of resistance to antimicrobials and heavy metals share the same or similar genetic mechanisms, such as: (i) coresistance: when mechanisms of resistance to metals and antimicrobials are encoded in the same mobile genetic element; or (ii) cross-resistance: when the same mechanism simultaneously confers resistance to metals and antimicrobials (Baker-Austin et al., 2006; Seiler & Berendonk, 2012). This similarity in resistance pathways can cause microorganisms in contact with one of these substances to develop resistance to metals or antimicrobials, or even to both, and this resistance is usually associated with mobile genetic elements, especially plasmids (Chattopadhyay & Grossart, 2011).

Several studies have shown that antimicrobial-resistant bacteria recovered from polluted environments were also resistant to heavy metals (Matyar et al., 2014; Hahn et al., 2015; Thomas et al., 2020). Matyar et al. (2014) examined a river in Turkey, and observed that the recovered bacteria showed resistance to a range of β-lactam antimicrobials and also resistance to metals Mn, Nickel (Ni), Zinc (Zn), Lead (Pb), Cd, and Fe. Hahn et al. (2015) evaluated the resistance profile of bacteria isolated from Rio dos Sinos (Brazil) and identified microorganisms resistant to several antimicrobials, mainly vancomycin, and also to heavy metals, especially Cu, Ni, and Cr. Thomas et al. (2020) analyzed soil samples collected from a polluted river in the United States and demonstrated that the samples exhibited a high profile of antimicrobial resistance genes and also heavy metal resistance genes such as Arsenic (As), Cu, Fe, Ni, and Zn.

When present as pollutants in aquatic environments, these elements can be highly associated with the development of AMR, as demonstrated by Chen et al. (2019). In their study, soil samples collected from a river located near a copper tailings dam in northern China were analyzed, and it was observed that the abundance of antimicrobial resistance genes was positively correlated with the concentration of metals present in the water as contaminants, these being As, Zn, and mainly Cd (Chen et al., 2019).

In this context, disasters involving mining dams cause the release of large amounts of waste, which contributes to the contamination of the aquatic environment by heavy metals, which may lead to changes in AMR-related phenotypes, as demonstrated in all six studies presented in the present review.

Some studies and reports have shown that the return of the environment to pre-collapse conditions takes a long period of time, and may often not even be estimated (Serra, 2018; IBAMA, 2015), thus making the environment a potential for development, maintenance, and spread of antimicrobial resistance.

Something of concern is that bacteria present in the aquatic environment contaminated by heavy metals that acquire antimicrobial resistance can contaminate fish and other aquatic organisms that live in these environments (Seiler & Berendonk, 2012). This can pose a serious risk to public health, as antimicrobial resistance genes can be transferred from environmental bacteria to human-associated bacteria through consumption of food contaminated with resistant strains (Enciso-Martínez et al., 2022).

Another important topic is the One Health approach, the collaborative effort of various health science professions to achieve optimal health for people, animals, and the environment (McEwen & Collignon, 2018). In the context of antimicrobial resistance, it is mainly driven by the use and abuse of these compounds in the human and animal sectors. Antimicrobials used clinically are not completely metabolized by the body, causing active molecules to be secreted through feces and urine, flowing into wastewater and can be shared between bacteria, including environmental bacteria. In this way, it is crucial to identify and characterize the sources of antimicrobial resistance emissions into the environment and, therefore, great importance has been given to this issue, considering an efficient collaboration between all the players involved (humans, animals, and the environment) to combat this very serious problem (Serna & Gonzalez-Zorn, 2022).

The present study had some limitations, such as the low number of studies found and the analysis of samples only in periods immediately after the disaster, making it not possible to identify chronic effects related to antimicrobial resistance. In this way, studies such as those exposed in this review are essential to better understand the effects that disasters involving mining dams, such as those in Minas Gerais, can cause to the environment, and also to human health, and it is important to carry out more research on the subject.

All studies presented in this review identified changes in the antimicrobial resistance profile of bacteria isolated from environments contaminated by metals after disasters. Disasters such as these open up questions about the possibility of inducing antimicrobial resistance by metals present as environmental contaminants, and further studies are essential, since antimicrobial resistance is a serious public health problem.

6 ACKNOWLEDGMENT

The authors would like to thank the Federal University of São João del-Rei, Campus CentroOeste Dona Lindu (UFSJ/CCO) for their support. This work was carried out with the support of the Coordination for the Improvement of Higher Education Personnel – Brazil (CAPES) – Financing Code 001 and the Research Support Foundation of the State of Minas Gerais (FAPEMIG proposals APQ01220-22 and APQ- 00208-19).

ABOUT THE AUTHORS

Lara Luiza Freitas de Oliveira

Mestre em Biotecnologia pelo Programa de Pós-graduação em Biotecnologia, da Universidade Federal de São João del-Rei, Campus Centro-Oeste Dona Lindu (UFSJ/CCO) e Bacharel em Bioquímica pela mesma instituição.

E-mail: [email protected]

ORCID ID: https://orcid.org/0000-0002-2115-0943

Shara Sevesquim Alcantara

Estudante de graduação em Farmácia pela Universidade Federal de São João del-Rei, Campus Centro-Oeste

Dona Lindu (UFSJ/CCO).

E-mail: [email protected]

ORCID ID: https://orcid.org/0009-0001-0943-1064

Rafael Sotero Caldeira

Graduado em Farmácia pela Universidade Federal de São João del-Rei, Campus Centro-Oeste Dona Lindu (UFSJ/CCO).

E-mail: [email protected]

ORCID ID: https://orcid.org/0009-0008-1602-2630

Anderson Kelvin Saraiva Macêdo

Doutor e Mestre em Biotecnologia, pelo Programa de Pós-graduação em Biotecnologia, da Universidade

Federal de São João del-Rei, Campus Centro-Oeste Dona Lindu (UFSJ/CCO). Graduado em Ciências

Biológicas pela Universidade Estadual da Paraíba (UEPB).

E-mail: [email protected]

ORCID ID: https://orcid.org/0000-0002-0404-1681

Hélio Batista dos Santos

Doutor e Mestre em Biologia Celular pela Universidade Federal de Minas Gerais (UFMG). Graduado em

Ciências Biológicas pela Universidade Estadual de Minas Gerais (UEMG). Professor Associado III na

Universidade Federal de São João del-Rei, Campus Centro-Oeste Dona Lindu (UFSJ/CCO).

E-mail: [email protected]

ORCID ID: https://orcid.org/0000-0001-6813-8522

Magna Cristina de Paiva

Doutora em Ciências Biológicas e Mestre em Microbiologia pela Universidade Federal de Minas Gerais

(UFMG). Graduada em Farmácia pela mesma instituição. Professora do curso de Farmácia na Universidade

Federal de São João del-Rei, Campus Centro-Oeste Dona Lindu (UFSJ/CCO).

E-mail: [email protected].

ORCID ID: https://orcid.org/0000-0001-9375-7261.

Ralph Gruppi Thomé

Doutor e Mestre em Biologia Celular pela Universidade Federal de Minas Gerais (UFMG). Graduado em

Ciências Biológicas pela mesma instituição. Professor na Universidade Federal de São João del-Rei, Campus

Centro-Oeste Dona Lindu (UFSJ/CCO) e Coordenador do Programa de Pós-graduação em Biotecnologia da UFSJ/CCO.

E-mail: [email protected].

ORCID ID: https://orcid.org/0000-0002-1779-5036.

Farah Maria Drumond Chequer

Doutora em Ciências e Mestre em Toxicologia pela Faculdade de Ciências Farmacêuticas de Ribeirão Preto

da Universidade de São Paulo (FCFRP-USP). Graduada em Farmácia/Bioquímica pela Universidade Federal

de Alfenas (UNIFAL). Professora na Universidade Federal de São João del-Rei, Campus Centro-Oeste Dona

Lindu (UFSJ/CCO) e é credenciada no Programa de Pós-graduação em Ciências Farmacêuticas da UFSJ/CCO.

E-mail: [email protected].

ORCID ID: https://orcid.org/0000-0003-3514-2132.