# | Rank | Similarity | Title + Abs. | Year | PMID |
|---|---|---|---|---|---|
| 0 | 1 | 2 | 3 | 4 | 5 |
| 9823 | 0 | 1.0000 | Transposition of an antibiotic resistance element in mycobacteria. Bacterial resistance to antibiotics is often plasmid-mediated and the associated resistance genes encoded by transposable elements. Mycobacteria, including the human pathogens Mycobacterium tuberculosis and M. leprae, are resistant to many antibiotics, and their cell-surface structure is believed to be largely responsible for the wide range of resistance phenotypes. Antibiotic-resistance plasmids have so far not been implicated in resistance of mycobacteria to antibiotics. Nevertheless, antibiotic-modifying activities such as aminoglycoside acetyltransferases and phosphotransferases have been detected in fast-growing species. beta-lactamases have also been found in most fast- and slow-growing mycobacteria. To date no mycobacterial antibiotic-resistance genes have been isolated and characterized. We now report the isolation, cloning and sequencing of a genetic region responsible for resistance to sulphonamides in M. fortuitum. This region also contains an open reading frame homologous to one present in Tn1696 (member of the Tn21 family) which encodes a site-specific integrase. The mycobacterial resistance element is flanked by repeated sequences of 880 base pairs similar to the insertion elements of the IS6 family found in Gram+ and Gram- bacteria. The insertion element is shown to transpose to different sites in the chromosome of a related fast-growing species, M. smegmatis. The characterization of this element should permit transposon mutagenesis in the analysis of mycobacterial virulence and related problems. | 1990 | 2163027 |
| 9822 | 1 | 0.9999 | Molecular mechanisms for transposition of drug-resistance genes and other movable genetic elements. Transposition is proposed to be responsible for the rapid evolution of multiply drug-resistant bacterial strains. Transposons, which carry the genes encoding drug resistance, are linear pieces of DNA that range in size from 2.5 to 23 kilobase pairs and always contain at their ends nucleotide sequences repeated in inverse order. In some transposons the terminal inverted repeat sequences are capable of independent movement and are called insertion sequences. Transposons carry a gene that encodes transposase(s), the enzyme(s) responsible for recombination of the transposon into another DNA molecule. Studies on transposable genetic elements in bacteria have not only given insight into the spread of antibiotic resistance but also into the process of DNA movement. | 1987 | 3035697 |
| 9820 | 2 | 0.9998 | The Tn21 subgroup of bacterial transposable elements. The Tn3 family of transposable elements is probably the most successful group of mobile DNA elements in bacteria: there are many different but related members and they are widely distributed in gram-negative and gram-positive bacteria. The Tn21 subgroup of the Tn3 family contains closely related elements that provide most of the currently known variation in Tn3-like elements in gram-negative bacteria and that are largely responsible for the problem of multiple resistance to antibiotics in these organisms. This paper reviews the structure, the mechanism of transposition, the mode of acquisition of accessory genes, and the evolution of these elements. | 1990 | 1963947 |
| 4467 | 3 | 0.9998 | PCR mapping of integrons reveals several novel combinations of resistance genes. The integron is a new type of mobile element which has evolved by a site-specific recombinational mechanism. Integrons consist of two conserved segments of DNA separated by a variable region containing one or more genes integrated as cassettes. Oligonucleotide probes specific for the conserved segments have revealed that integrons are widespread in recently isolated clinical bacteria. Also, by using oligonucleotide probes for several antibiotic resistance genes, we have found novel combinations of resistance genes in these strains. By using PCR, we have determined the content and order of the resistance genes inserted between the conserved segments in the integrons of these clinical isolates. PCR mapping of integrons can be a useful epidemiological tool to study the evolution of multiresistance plasmids and transposons and dissemination of antibiotic resistance genes. | 1995 | 7695304 |
| 4469 | 4 | 0.9998 | Integrons: an antibiotic resistance gene capture and expression system. Bacteria can transfer genetic information to provide themselves with protection against most antibiotics. The acquisition of resistance gene arrays involves genetic mobile elements like plasmids and transposons. Another class of genetic structures, termed integrons, have been described and contain one or more gene cassettes located at a specific site. Integrons are defined by an intl gene encoding an integrase, a recombination site attl and a strong promoter. At least six classes of integrons have been determined according to their intl gene. Classes 1, 2 and 3 are the most studied and are largely implicated in the dissemination of antibiotic resistance. A gene cassette includes an open reading frame and, at the 3'-end, a recombination site attC. Integration or excision of cassettes occur by a site-specific recombination mechanism catalyzed by the integrase. However, insertion can occur, albeit rarely, at non-specific sites leading to a stable situation for the cassette. Cassettes are transcribed from the common promoter located in the 5'-conserved segment and expression of distal genes is reduced by the presence of upstream cassettes. Most gene cassettes encode antibiotic resistant determinants but antiseptic resistant genes have also been described. Integrons seem to have a major role in the spread of multidrug resistance in gram-negative bacteria but integrons in gram-positive bacteria were described recently. Moreover, the finding of super-integrons with gene-cassettes coding for other determinants (biochemical functions, virulence factors) in Vibrio isolates dating from 1888 suggests the likely implication of this multicomponent cassette-integron system in bacterial genome evolution before the antibiotic era and to a greater extent than initially believed. | 2000 | 10987194 |
| 9821 | 5 | 0.9998 | Mercury resistance (mer) operons in enterobacteria. Mercury resistance is found in many genera of bacteria. Common amongst enterobacteria are transposons related to Tn21, which is both mercuric ion- and streptomycin-/spectinomycin- and sulphonamide-resistant. Other Tn21-related transposons often have different antibiotic resistances compared with Tn21, but share many non-antibiotic-resistance genes with it. In this article we discuss possible mechanisms for the evolution of Tn21 and related genetic elements. | 2002 | 12196175 |
| 9827 | 6 | 0.9998 | Evolution of bacterial resistance to antibiotics during the last three decades. Bacterial resistance to antibiotics is often plasmid-mediated and the associated genes encoded by transposable elements. These elements play a central role in evolution by providing mechanisms for the generation of diversity and, in conjunction with DNA transfer systems, for the dissemination of resistances to other bacteria. At the University Hospital of Zaragoza, extensive efforts have been made to define both the dissemination and evolution of antibiotic resistance by studying the transferable R plasmids and transposable elements. Here we describe the research on bacterial resistance to antibiotics in which many authors listed in the references have participated. The aspects of bacterial resistance dealt with are: (i) transferable resistance mediated by R plasmids in Gram-negative bacteria, (ii) R plasmid-mediated resistance to apramycin and hygromycin in clinical strains, (iii) the transposon Tn1696 and the integron In4, (iv) expression of Escherichia coli resistance genes in Haemophilus influenzae, (v) aminoglycoside-modifying-enzymes in the genus Mycobacterium with no relation to resistance, and (vi) macrolide-resistance and new mechanisms developed by Gram-positive bacteria. | 1998 | 10943375 |
| 4468 | 7 | 0.9998 | Mobile gene cassettes and integrons: moving antibiotic resistance genes in gram-negative bacteria. In Gram-negative pathogens, multiple antibiotic resistance is common and many of the known resistance genes are contained in mobile gene cassettes. Cassettes can be integrated into or deleted from their receptor elements, the integrons, or infrequently may be integrated at other locations via site-specific recombination catalysed by an integron-encoded recombinase. As a consequence, arrays of several different antibiotic resistance genes can be created. Over 40 gene cassettes and three distinct classes of integrons have been identified to date. Cassette-associated genes conferring resistance to beta-lactams, aminoglycosides, trimethoprim, chloramphenicol, streptothricin and quaternary ammonium compounds used as antiseptics and disinfectants have been found. In addition, most members of the commonest family of integrons (class 1) include a sulfonamide resistance determinant in the backbone structure. Integrons are themselves translocatable, though most are defective transposon derivatives. Integron movement allows transfer of the cassette-associated resistance genes from one replicon to another or into another active transposon which facilitates spread of integrons that are transposition defective. Horizontal transfer of the resistance genes can be achieved when an integron containing one or more such genes is incorporated into a broad-host-range plasmid. Likewise, single cassettes integrated at secondary sites in a broad-host-range plasmid can also move across species boundaries. | 1997 | 9189642 |
| 9867 | 8 | 0.9998 | Mosaic plasmids are abundant and unevenly distributed across prokaryotic taxa. Mosaic plasmids, plasmids composed of genetic elements from distinct sources, are associated with the spread of antibiotic resistance genes. Transposons are considered the primary mechanism for mosaic plasmid formation, though other mechanisms have been observed in specific instances. The frequency with which mosaic plasmids have been described suggests they may play an important role in plasmid population dynamics. Our survey of the confirmed plasmid sequences available from complete and draft genomes in the RefSeq database shows that 46% of them fit a strict definition of mosaic. Mosaic plasmids are also not evenly distributed over the taxa represented in the database. Plasmids from some genera, including Piscirickettsia and Yersinia, are almost all mosaic, while plasmids from other genera, including Borrelia, are rarely mosaic. While some mosaic plasmids share identical regions with hundreds of others, the median mosaic plasmid only shares with 8 other plasmids. When considering only plasmids from finished genomes (51.6% of the total), mosaic plasmids have significantly higher proportions of transposase and antibiotic resistance genes. Conversely, only 56.6% of mosaic fragments (DNA fragments shared between mosaic plasmids) contain a recognizable transposase gene, and only 1.2% of mosaic fragments are flanked by inverted repeats. Mosaic fragments associated with the IS26 transposase gene are 3.8-fold more abundant than any other sequence shared between mosaic plasmids in the database, though this is at least partly due to overrepresentation of Enterobacteriaceae plasmids. Mosaic plasmids are a complicated trait of some plasmid populations, only partly explained by transposition. Though antibiotic resistance genes led to the identification of many mosaic plasmids, mosaic plasmids are a broad phenomenon encompassing many more traits than just antibiotic resistance. Further research will be required to determine the influence of ecology, host repair mechanisms, conjugation, and plasmid host range on the formation and influence of mosaic plasmids. AUTHOR SUMMARY: Plasmids are extrachromosomal genetic entities that are found in many prokaryotes. They serve as flexible storage for genes, and individual cells can make substantial changes to their characteristics by acquiring, losing, or modifying a plasmid. In some pathogenic bacteria, such as Escherichia coli, antibiotic resistance genes are known to spread primarily on plasmids. By analyzing a database of 8592 plasmid sequences we determined that many of these plasmids have exchanged genes with each other, becoming mosaics of genes from different sources. We next separated these plasmids into groups based on the organism they were isolated from and found that different groups had different fractions of mosaic plasmids. This result was unexpected and suggests that the mechanisms and selective pressures causing mosaic plasmids do not occur evenly over all species. It also suggests that plasmids may provide different levels of potential variation to different species. This work uncovers a previously unrecognized pattern in plasmids across prokaryotes, that could lead to new insights into the evolutionary role that plasmids play. | 2019 | 30797764 |
| 260 | 9 | 0.9997 | Improved antibiotic resistance gene cassette for marker exchange mutagenesis in Ralstonia solanacearum and Burkholderia species. Marker exchange mutagenesis is a fundamental approach to understanding gene function at a molecular level in bacteria. New plasmids carrying a kanamycin resistance gene or a trimethoprim resistance gene were constructed to provide antibiotic resistance cassettes for marker exchange mutagenesis in Ralstonia solanacearum and many antibiotic-resistant Burkholderia spp. Insertion sequences present in the flanking sequences of the antibiotic resistance cassette were removed to prevent aberrant gene replacement and polar mutation during mutagenesis in wild-type bacteria. Plasmids provided in this study would be convenient for use in gene cassettes for gene replacement in other Gram-negative bacteria. | 2011 | 21538255 |
| 4835 | 10 | 0.9997 | Genetic and biochemical basis of resistance of Enterobacteriaceae to beta-lactam antibiotics. Resistance to beta-lactam drugs is usually determined by genes mediating the production of beta-lactamases. These genes can be located on resistance plasmids or on the chromosome. Resistance to drugs which have been available for many years is mostly transposable. Although the origin of these genes is not known, it is possible to draw a hypothetical flow diagram of the evolution of resistance genes in general. The mechanism of resistance although mediated in Gram-negative bacteria mostly by beta-lactamases cannot be simply described as the hydrolytic function of the enzyme. It is a complex interaction involving the affinity of the drug for the target and the lactamase, the amount of drug in the periplasmic space, the amount of enzyme and the number of lethal target sites. Usually one of these factors is predominant. | 1986 | 3491818 |
| 9819 | 11 | 0.9997 | Site-specific recombination and shuffling of resistance genes in transposon Tn21. Many multidrug-resistant transposons found in natural isolates of Gram-negative bacteria are close relatives of Tn21. Thus, the Tn21 subgroup of the Tn3 family of transposable elements is the most successful homogeneous group in acquiring resistance to newly introduced antibiotics. This paper summarizes the mode of acquisition of resistance genes by these elements. | 1991 | 1660178 |
| 4465 | 12 | 0.9997 | Genetic analyses of sulfonamide resistance and its dissemination in gram-negative bacteria illustrate new aspects of R plasmid evolution. In contrast to what has been observed for many other antibiotic resistance mechanisms, there are only two known genes encoding plasmid-borne sulfonamide resistance. Both genes, sulI and sulII, encode a drug-resistant dihydropteroate synthase enzyme. In members of the family Enterobacteriaceae isolated from several worldwide sources, plasmid-mediated resistance to sulfonamides could be identified by colony hybridization as being encoded by sulI, sulII, or both. The sulI gene was in all cases found to be located in the newly defined, mobile genetic element, recently named an integron, which has been shown to contain a site-specific recombination system for the integration of various antibiotic resistance genes. The sulII gene was almost exclusively found as part of a variable resistance region on small, nonconjugative plasmids. Colony hybridization to an intragenic probe, restriction enzyme digestion, and nucleotide sequence analysis of small plasmids indicated that the sulII gene and contiguous sequences represent an independently occurring region disseminated in the bacterial population. The sulII resistance region was bordered by direct repeats, which in some plasmids were totally or partially deleted. The prevalence of sulI and sulII could thus be accounted for by their stable integration in transposons and in plasmids that are widely disseminated among gram-negative bacteria. | 1991 | 1952855 |
| 9828 | 13 | 0.9997 | Antibiotic resistance: genetic mechanisms and mobility. Based on the current knowledge, resistance genes seems mainly to originate in the organisms which produce antibiotics (Davies 1994). We lack considerably in the understanding of how these genes were transferred to pathogenic bacteria, and due to the enormous diversity of e.g. the soil flora, it is doubtful that we will ever obtain more that a faint picture of this. In Gram negative bacteria, more and more resistance genes are demonstrated to be located in integrons (e.g. beta-lactamase and streptomycin resistance genes in Salmonella Typhimurium DT104 (Sandvang et al. in press)). Integrons seem primarily to act as insertion sites for resistance genes. The origin of integrons as well as the resistance gene cassettes that are the other essential element of this system, is largely unknown (Hall & Collis 1995). Integrons can be located in the chromosome, in transposons, which have the ability to copy them themselves to other DNA molecules, or on plasmids. The emergence of resistant bacteria normally happens because of selection for a resistant clone of bacteria. Several mechanisms, however, exists by which the resistance genes can be transferred from one bacteria to another. Conjugation, mediated by plasmids or conjugative transposons, is currently the most well established of these mechanisms. Still, however, the selection pressure created by the use of antibiotics determines whether bacteria that have newly acquired a resistance gene expand to dominate in the population or remains a blink in history. | 1999 | 10783713 |
| 9830 | 14 | 0.9997 | Mechanisms of Conjugative Transfer and Type IV Secretion-Mediated Effector Transport in Gram-Positive Bacteria. Conjugative DNA transfer is the most important means to transfer antibiotic resistance genes and virulence determinants encoded by plasmids, integrative conjugative elements (ICE), and pathogenicity islands among bacteria. In gram-positive bacteria, there exist two types of conjugative systems, (i) type IV secretion system (T4SS)-dependent ones, like those encoded by the Enterococcus, Streptococcus, Staphylococcus, Bacillus, and Clostridia mobile genetic elements and (ii) T4SS-independent ones, as those found on Streptomyces plasmids. Interestingly, very recently, on the Streptococcus suis genome, the first gram-positive T4SS not only involved in conjugative DNA transfer but also in effector translocation to the host was detected. Although no T4SS core complex structure from gram-positive bacteria is available, several structures from T4SS protein key factors from Enterococcus and Clostridia plasmids have been solved. In this chapter, we summarize the current knowledge on the molecular mechanisms and structure-function relationships of the diverse conjugation machineries and emerging research needs focused on combatting infections and spread of multiple resistant gram-positive pathogens. | 2017 | 29536357 |
| 9829 | 15 | 0.9997 | Promiscuous transfer of drug resistance in gram-negative bacteria. Bacterial conjugation is a major mechanism for the spread of antibiotic-resistance genes in pathogenic organisms. In gram-negative bacteria, broad-host-range drug-resistance plasmids mediate genetic exchange between many unrelated species. The mechanism of conjugation encoded by the broad-host-range IncP plasmid RK2 has been studied in detail. The location and sequence of the transfer origin of RK2 has been determined. Several barriers limit plasmid transfer between unrelated bacteria: interactions at the cell surface may prevent effective mating contact, restriction systems may degrade foreign DNA, or the plasmid may not replicate in the new host. RK2 has evolved specific mechanisms by which it overcomes these barriers; this plasmid can mediate the transfer of resistance to most gram-negative bacteria. | 1984 | 6143782 |
| 4419 | 16 | 0.9997 | Epidemiology of tetracycline-resistance determinants. Resistance to tetracycline is generally due either to energy-dependent efflux of tetracycline or to protection of the bacterial ribosomes from the action of tetracycline. The genes that encode this resistance are normally acquired via transferable plasmids and/or transposons. Tet determinants have been found in a wide range of Gram-positive and Gram-negative bacteria and have reduced the effectiveness of therapy with tetracycline. | 1994 | 7850200 |
| 4377 | 17 | 0.9997 | Pathogenicity and other genomic islands in plant pathogenic bacteria. SUMMARY Pathogenicity islands (PAIs) were first described in uropathogenic E. coli. They are now defined as regions of DNA that contain virulence genes and are present in the genome of pathogenic strains, but absent from or only rarely present in non-pathogenic variants of the same or related strains. Other features include a variable G+C content, distinct boundaries from the rest of the genome and the presence of genes related to mobile elements such as insertion sequences, integrases and transposases. Although PAIs have now been described in a wide range of both plant and animal pathogens it has become evident that the general features of PAIs are displayed by a number of regions of DNA with functions other than pathogenicity, such as symbiosis and antibiotic resistance, and the general term genomic islands has been adopted. This review will describe a range of genomic islands in plant pathogenic bacteria including those that carry effector genes, phytotoxins and the type III protein secretion cluster. The review will also consider some medically important bacteria in order to discuss the range, acquisition and stabilization of genomic islands. | 2003 | 20569400 |
| 255 | 18 | 0.9997 | Versatile nourseothricin and streptomycin/spectinomycin resistance gene cassettes and their use in chromosome integration vectors. An obstacle for the development of genetic systems for many bacteria is the limited number of antibiotic selection markers, especially for bacteria that are intrinsically antibiotic resistant or where utilization of such markers is strictly regulated. Here we describe the development of versatile cassettes containing nourseothricin, streptomycin/spectinomycin, and spectinomycin selection markers. The antibiotic resistance genes contained on these cassettes are flanked by loxP sites with allow their in vivo excision from the chromosome of target bacteria using Cre recombinase. The respective selection marker cassettes were used to derive mini-Tn7 elements that can be used for single-copy insertion of genes into bacterial chromosomes. The utility of the selection markers was tested by insertion of the resulting mini-Tn7 elements into the genomes of Burkholderia thailandensis and B. pseudomallei efflux pump mutants susceptible to aminoglycosides, aminocyclitols, and streptothricins, followed by Cre-mediated antibiotic resistance marker excision. The versatile nourseothricin, streptomycin/spectinomycin and spectinomycin resistance loxP cassette vectors described here extend the repertoire of antibiotic selection markers for genetic manipulation of diverse bacteria that are susceptible to aminoglycosides and aminocyclitols. | 2016 | 27457407 |
| 4488 | 19 | 0.9997 | The cfr and cfr-like multiple resistance genes. The Cfr methyl transferase causes an RNA methylation of the bacterial ribosomes impeding reduced or abolished binding of many antibiotics acting at the peptidyl transferase center. It provides multi-resistance to eight classes of antibiotics, most of which are in clinical and veterinary use. The cfr gene is found in various bacteria in many geographical locations and placed on plasmids or associated with transposons. Cfr-related genes providing similar resistance have been identified in Bacillales, and now also in the pathogens Clostridium difficile and Enterococcus faecium. In addition, the presence of the cfr gene has been detected in harbours and food markets. | 2018 | 29378339 |