DDI - Teses de doutoramento
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Browsing DDI - Teses de doutoramento by Subject "Antibiotic Resistance"
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- Assessing antibiotic resistance in Gram negative bacteria from animals and the wider environmentPublication . Jones-Dias, Daniela; Caniça, Manuela; Nogueira, IsabelThe alarming increase in the levels of antibiotic resistant bacteria in clinical practice launched the call for a broader understanding of this event. This Ph.D. thesis aimed to unravel the main mobile antibiotic resistance determinants circulating in Gram negative bacteria from non-human sources, showing the contribution of mobile genetic elements for the overall process. The susceptibility and molecular epidemiological studies performed on different collections of bacterial isolates showed the predominance of multidrug resistant Escherichia coli in animals of different origins, soil and vegetables. E. coli and other species of Gram negative bacteria were related with carriage of diverse antibiotic resistance genes [e.g. blaCTX-M-1, blaCTX-M-15, blaCMY-2, blaGES-11, qnrS1, aac(6’)-Ib-cr, strAB, tet, drfA, aadA, mcr-1] that were associated with a transferable genetic support. Indeed, an assortment of mobile genetic elements (e.g. IncI1 and IncF plasmids, ISEcp1 insertion sequences, Tn402 and Tn7 transposons and class 1, 2 and 3 integrons) was detected in the genetic proximity of those antibiotic resistance genes, suggesting their profound involvement, not only in interspecies dispersion, but also in the movement of the genes within the cell. Specific genomic investigation of two Enterobactericeae isolates and the proteomic study of a third, underscored the potential of massive omic approaches to study antibiotic resistance as a global process. One of the key findings released from these studies is that antibiotic resistance is not only linked to virulence and pathogenicity, but can also be connected to core bacterial metabolic processes. The results obtained throughout this thesis extend our knowledge on the distribution of mobile antibiotic resistance genes in animals, environment and, ultimately, in the food chain. If the gathered results increased our concerns towards the current distribution of antibiotic resistant bacteria, they can also be an encouragement to address this problem at a global scale.
- Decrypting the diversity of microbiome in aquaculturePublication . Salgueiro, Vanessa; Caniça, Manuela; Manageiro, Vera; Nogueira, IsabelAquaculture can play an important role in reducing the overexploitation of natural re- sources and feeding the world’s growing population. However, the use of e.g., antibiotics in aquaculture can favor the development of resistant bacteria and jeopardize the safety of its products. Thus, this Ph.D. thesis aimed to contribute to the deciphering of aquaculture’s mi- crobiome and resistome, as well as to the understanding of the role of mobile genetic elements (MGE) in the dissemination of resistance genes in these environments. Several approaches were used, to obtain the results that most reflect the microbiome and resistome of seabream and bivalve mollusks from aquaculture. All microbiomes studied were very diverse, encompassing commensal and pathogenic bacteria from seabream and bivalve mollusks (e.g., Aeromonas,Kocuria, Pseudomonas and Vibrio genera), as well as bacteria important in human medicine (e.g., Staphylococcus aureus, Escherichia coli and Klebsiella pneumoniae). Twenty-one new se- quence types were described in Aeromonas spp., Citrobacter sp., Enterobacter spp., Shewanella spp., Staphylococcus sp. and Vibrio spp. Decreased susceptibilities to phenicols, oxytetracy- cline, β-lactams (namely carbapenems), quinolones, glycopeptides, mupirocin, erythromycin, and colistin were found. The resistome also revealed a great diversity of genes in all samples studied associated with antibiotics (e.g., blaTEM-1B, mecA, sul2, mcr-9.1), disinfectants (e.g.,formA-type), and heavy metals (e.g., sil) resistance. Twenty-five different genes related with increased virulence were also detected. Thirteen new β-lactams resistance genes were identi- fied (e.g., blaCTX-M-246, blaFOX-18, and blaOXA-958) and 35 other resistance genes, namely for antibi- otics (e.g., mcr-9 and qnrD2), heavy metals (e.g., emrA and mdtE) and disinfectants ( sitABCD- type), and virulence factors (e.g., astA and hlyF) were here described for the first time associated with aquaculture. Our results suggest that some of these resistance genes (e.g., erm(T)-type,qnrB19, catA1-type, tet(A), dfrA-type, aph(6)-Id, qacE∆ 1 and merA) are being disseminated by MGE such as plasmids, class 1 integrons, and Tn As1. These findings not only expand our knowledge about aquaculture’s microbiome and resistome, but also provide the necessary xiv information to implement the most suitable measures to control antibiotic resistance in aqua- culture environments.