Here, we identified four β-lactamase genes, three of which were assigned to Class A β-lactamase, and one to Class D; no genes belonging to Classes B (metallo β-lactamases) and Class C were found (Supporting Information Fig. S1). We cannot conclude from these results that there are no Class B or Cyclopamine manufacturer C β-lactamases presented in our gut; further efforts should be made to delineate the whole profile of β-lactamase genes in human gut. The eight d-alanine-d-alanine ligase genes encoding resistance to d-cycloserine were assigned separately to two distinct groups
in the phylogenetic tree but the genes in each group are very close to each other, which suggested that the d-cycloserine resistance genes we identified were probably derived from phylogenetically closely linked gut bacteria of two major taxa (Fig. S2). Four bifunctional proteins with both domains involved in resistance to aminoglycoside Doramapimod antibiotics have been reported previously (Ferretti et al., 1986; Centron & Roy, 2002; Dubois et al., 2002; Mendes et al., 2004). In all cases, these bifunctional proteins had expanded substrate specificity. Pathogenic bacteria with these proteins would have a selective advantage in a clinical environment. Recently,
the kanamycin-resistance protein Kan4, which has an AAC(6′) domain fused to an acetyltransferase domain, was identified from soil using functional metagenomics. Functional analysis showed that only the AAC(6′) domain conferred kanamycin resistance (Donato et al., 2010). In this study, we used a functional metagenomic method to characterize ARGs in human gut microbiota. A novel kanamycin-resistance protein with an AAC(6′) domain fused to a hypothetical protein domain was identified. The kanamycin resistance of the N-terminal domain of this novel protein was confirmed, but the function of the C-terminus was unknown. According to conserved domain searching
through VAV2 NCBI, the C-terminus just matched a domain of unknown function (DUF2007). Therefore, whether the C-terminus of this protein correlated to substrate specificity or others was unclear, and its exact function needs to be further investigated. In our screen for tetracycline resistance, three known ribosomal protection-type genes were obtained: tet(O), tet(W), and tet(32). A tetracycline efflux gene tet(40) was also found in the same clone as tet(O). In a previous study using microarray analysis, tet(O) and tet(W) were the most prevalent tetracycline-resistance genes in fecal samples from adults from six European countries (Seville et al., 2009). In another study, numerous tet(W) sequences were uncovered through a functional metagenomic screen of antibiotic resistance in gut bacteria from two adult individuals in the USA (Sommer et al., 2009). The tetracycline efflux gene tet(40) was first identified in a human bacterial isolate and in a human gut metagenomic library. In both cases, it was linked to the mosaic tet(O/32/O) (Kazimierczak et al., 2008).
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