# | Rank | Similarity | Title + Abs. | Year | PMID |
|---|---|---|---|---|---|
| 0 | 1 | 2 | 3 | 4 | 5 |
| 4470 | 0 | 1.0000 | R-factors in gram-positive and gram-negative aerobic bacteria selected by antimicrobial therapy. Populations of resistant bacteria emerge by the operation of selective pressure on resistant bacteria. The acquisition of resistance by sensitive bacteria is dependent upon the genetic determinant of the resistance, and its ability to move between different bacterial cells and within cells between different replicons. In contrast to chromosomal mediated resistance, plasmids and transposable elements coding for resistance to antibiotics have been the major factors in the spread of resistance and the prevalence of resistant bacteria in humans, farm animals and poultry. Different types of R-factors can be described. Resistance to ampicillin, tetracycline, chloramphenicol, gentamicin, trimethoprim, erythromycin may exemplify epidemiological aspects of resistance genes in Gram-negative and Gram-positive bacteria. The ecological destiny of resistant bacterial populations suggests the role of other factors than antibiotic resistance: characters of a particular host, host-plasmid relationship and properties which may lead to survival and adaptation in a given niche. | 1986 | 3547625 |
| 4151 | 1 | 0.9999 | Evolutionary relationships among genes for antibiotic resistance. The genes that determine resistance to antibiotics are commonly found encoded by extrachromosomal elements in bacteria. These were described first in Enterobacteriaceae and subsequently in a variety of other genera; their spread is associated with the increased use of antibiotics in human and animal medicine. Antibiotic-resistance genes that determine the production of enzymes which modify (detoxify) the antibiotics have been detected in antibiotic-producing organisms. It has been suggested that the producing strains provided the source of antibiotic-resistance genes that were then 'picked-up' by recombination. Recent studies of the nucleotide sequence of certain antibiotic-resistance genes indicate regions of strong homology in the encoded proteins. The implications of these similarities are discussed. | 1984 | 6559117 |
| 4423 | 2 | 0.9999 | Inactivation of antibiotics and the dissemination of resistance genes. The emergence of multidrug-resistant bacteria is a phenomenon of concern to the clinician and the pharmaceutical industry, as it is the major cause of failure in the treatment of infectious diseases. The most common mechanism of resistance in pathogenic bacteria to antibiotics of the aminoglycoside, beta-lactam (penicillins and cephalosporins), and chloramphenicol types involves the enzymic inactivation of the antibiotic by hydrolysis or by formation of inactive derivatives. Such resistance determinants most probably were acquired by pathogenic bacteria from a pool of resistance genes in other microbial genera, including antibiotic-producing organisms. The resistance gene sequences were subsequently integrated by site-specific recombination into several classes of naturally occurring gene expression cassettes (typically "integrons") and disseminated within the microbial population by a variety of gene transfer mechanisms. Although bacterial conjugation once was believed to be restricted in host range, it now appears that this mechanism of transfer permits genetic exchange between many different bacterial genera in nature. | 1994 | 8153624 |
| 4471 | 3 | 0.9999 | Update on acquired tetracycline resistance genes. This mini-review summarizes the changes in the field of bacterial acquired tetracycline resistance (tet) and oxytetracycline (otr) genes identified since the last major review in 2001. Thirty-eight acquired tetracycline resistant (Tc(r)) genes are known of which nine are new and include five genes coding for energy-dependent efflux proteins, two genes coding for ribosomal protection proteins, and two genes coding for tetracycline inactivating enzymes. The number of inactivating enzymes has increased from one to three, suggesting that work needs to be done to determine the role these enzymes play in bacterial resistance to tetracycline. In the same time period, 66 new genera have been identified which carry one or more of the previously described 29 Tc(r) genes. Included in the new genera is, for the first time, an obligate intracellular pathogen suggesting that this sheltered group of bacteria is capable of DNA exchange with non-obligate intracellular bacteria. The number of genera carrying ribosomal protection genes increased dramatically with the tet(M) gene now identified in 42 genera as compared with 24 and the tet(W) gene found in 17 new genera as compared to two genera in the last major review. New conjugative transposons, carrying different ribosomal protection tet genes, have been identified and an increase in the number of antibiotic resistance genes linked to tet genes has been found. Whether these new elements may help to spread the tet genes they carry to a wider bacterial host range is discussed. | 2005 | 15837373 |
| 4419 | 4 | 0.9999 | 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 |
| 3819 | 5 | 0.9999 | Enhancement of bacterial competitive fitness by apramycin resistance plasmids from non-pathogenic Escherichia coli. The study of antibiotic resistance has in the past focused on organisms that are pathogenic to humans or animals. However, the development of resistance in commensal organisms is of concern because of possible transfer of resistance genes to zoonotic pathogens. Conjugative plasmids are genetic elements capable of such transfer and are traditionally thought to engender a fitness burden on host bacteria. In this study, conjugative apramycin resistance plasmids isolated from newborn calves were characterized. Calves were raised on a farm that had not used apramycin or related aminoglycoside antibiotics for at least 20 months prior to sampling. Of three apramycin resistance plasmids, one was capable of transfer at very high rates and two were found to confer fitness advantages on new Escherichia coli hosts. This is the first identification of natural plasmids isolated from commensal organisms that are able to confer a fitness advantage on a new host. This work indicates that reservoirs of antibiotic resistance genes in commensal organisms might not decrease if antibiotic usage is halted. | 2006 | 17148431 |
| 4417 | 6 | 0.9999 | Genetic mobility and distribution of tetracycline resistance determinants. Since 1953, tetracycline-resistant bacteria have been found increasingly in humans, animals, food and the environment. Tetracycline resistance is normally due to the acquisition of new genes and is primarily due to either energy-dependent efflux of tetracycline or protection of the ribosomes from its action. Gram-negative efflux genes are frequently associated with conjugative plasmids, whereas Gram-positive efflux genes are often found on small mobilizable plasmids or in the chromosome. The ribosomal protection genes are generally associated with conjugative transposons which have a preference for the chromosome. Recently, tetracycline resistance genes have been found in the genera Mycobacterium, Nocardia, Streptomyces and Treponema. The Tet M determinant codes for a ribosomal protection protein which can be found in Gram-positive, Gram-negative, cell-wall-free, aerobic, anaerobic, pathogenic, opportunistic and normal flora species. This promiscuous nature may be correlated with its location on a conjugative transposon and its ability to cross most biochemical and physical barriers found in bacteria. The Tet B efflux determinant is unlike other efflux gene products because it confers resistance to tetracycline, doxycycline and minocycline and has the widest host range of all Gram-negative efflux determinants. We have hypothesized that mobility and the environment of the bacteria may help influence the ultimate host range of specific tet genes. If we are to reverse the trend towards increasingly antibiotic-resistant pathogenic bacteria, we will need to change how antibiotics are used in both human and animal health as well as food production. | 1997 | 9189643 |
| 4144 | 7 | 0.9999 | The diversity of antimicrobial resistance genes among staphylococci of animal origin. Staphylococci of animal origin harbor a wide variety of resistance genes. So far, more than 40 different resistance genes have been identified in staphylococci from animals. This includes genes that confer resistance to virtually all classes of antimicrobial agents approved for use in animals, such as penicillins, cephalosporins, tetracyclines, macrolides, lincosamides, phenicols, aminoglycosides, aminocyclitols, pleuromutilins, and diaminopyrimidines. The gene products of some of these resistance genes confer resistance to only specific members of a class of antimicrobial agents, whereas others confer resistance to the entire class or even to members of different classes of antimicrobial agents. The resistance mechanisms specified by the resistance genes fall into three major categories: (i) enzymatic inactivation, (ii) active efflux, or (iii) protection/modification/replacement of the cellular target sites of the antimicrobial agents. Mobile genetic elements, in particular plasmids and transposons, play a major role as carriers of antimicrobial resistance genes in animal staphylococci. They facilitate the exchange of resistance genes with staphylococci of human origin but also with other Gram-positive bacteria. | 2013 | 23499306 |
| 4416 | 8 | 0.9999 | Tetracycline resistance determinants: mechanisms of action, regulation of expression, genetic mobility, and distribution. Tetracycline-resistant bacteria were first isolated in 1953 from Shigella dysenteriae, a bacterium which causes bacterial dysentery. Since then tetracycline-resistant bacterial have been found in increasing numbers of species and genera. This has resulted in reduced effectiveness of tetracycline therapy over time. Tetracycline resistance is normally due to the acquisition of new genes often associated with either a mobile plasmid or a transposon. These tetracycline resistance determinants are distinguishable both genetically and biochemically. Resistance is primarily due to either energy-dependent efflux of tetracycline or protection of the ribosomes from the action of tetracycline. Gram-negative tetracycline efflux proteins are linked to repressor proteins which in the absence of tetracycline block transcription of the repressor and structural efflux genes. In contrast, expression of the Gram-positive tetracycline efflux genes and some of the ribosomal protection genes appears to be regulated by attenuation of mRNA transcription. Specific tetracycline resistance genes have been identified in 32 Gram-negative and 22 Gram-positive genera. Tetracycline-resistant bacteria are found in pathogens, opportunistic and normal flora species. Tetracycline-resistant bacteria can be isolated from man, animals, food, and the environment. The nonpathogens in each of these ecosystems may play an important role as reservoirs for the antibiotic resistance genes. It is clear that if we are to reverse the trend toward increasingly antibiotic-resistant pathogenic bacteria we will need to change how antibiotics are used in both human and animal health and food production. | 1996 | 8916553 |
| 4145 | 9 | 0.9999 | Antimicrobial Resistance among Staphylococci of Animal Origin. Antimicrobial resistance among staphylococci of animal origin is based on a wide variety of resistance genes. These genes mediate resistance to many classes of antimicrobial agents approved for use in animals, such as penicillins, cephalosporins, tetracyclines, macrolides, lincosamides, phenicols, aminoglycosides, aminocyclitols, pleuromutilins, and diaminopyrimidines. In addition, numerous mutations have been identified that confer resistance to specific antimicrobial agents, such as ansamycins and fluoroquinolones. The gene products of some of these resistance genes confer resistance to only specific members of a class of antimicrobial agents, whereas others confer resistance to the entire class or even to members of different classes of antimicrobial agents, including agents approved solely for human use. The resistance genes code for all three major resistance mechanisms: enzymatic inactivation, active efflux, and protection/modification/replacement of the cellular target sites of the antimicrobial agents. Mobile genetic elements, in particular plasmids and transposons, play a major role as carriers of antimicrobial resistance genes in animal staphylococci. They facilitate not only the exchange of resistance genes among members of the same and/or different staphylococcal species, but also between staphylococci and other Gram-positive bacteria. The observation that plasmids of staphylococci often harbor more than one resistance gene points toward coselection and persistence of resistance genes even without direct selective pressure by a specific antimicrobial agent. This chapter provides an overview of the resistance genes and resistance-mediating mutations known to occur in staphylococci of animal origin. | 2018 | 29992898 |
| 4424 | 10 | 0.9999 | Gene transfer, gentamicin resistance and enterococci. Enterococci are versatile pathogens by virtue of their ability to exhibit low-level intrinsic resistance to clinically useful antibiotics and their tolerance to adverse environmental conditions. In the last 20 years these pathogens have become progressively more difficult to treat because of their aptitude for acquiring antibiotic-resistance genes. Of increasing concern is the rapid dissemination of the AAC6'-APH2" bi-functional aminoglycoside modifying enzyme. This enzyme confers high-level resistance to gentamicin and all other related aminoglycosides with the exception of streptomycin. The gene conferring this phenotype has been associated with both narrow and broad host range plasmids, and has recently been found on conjugative transposons. The nature of these conjugative elements raises the possibility of the resistance gene spreading to other pathogenic bacteria. | 1997 | 9261754 |
| 4472 | 11 | 0.9999 | Conjugative plasmids in bacteria of the 'pre-antibiotic' era. Antibiotic resistance is common in bacteria that cause disease in man and animals and is usually determined by plasmids. The prevalence of such plasmids, and the range of drugs to which they confer resistance, have increased greatly in the past 25 yr. It has become clear from work in many laboratories that plasmids have acquired resistance genes, of ultimately unknown origin, as insertions into their circular DNA. The intensive use of antibiotics since their introduction in the 1940s can explain the spread of plasmids that have acquired such genes but little is known of the incidence of plasmids in pathogenic bacteria before the widespread use of antibiotics in medicine. E.D.G. Murray collected strains of Enterobacteriaceae from 1917 to 1954; we now report that 24% of these encode information for the transfer of DNA from one bacterium to another. From at least 19% of the strains, conjugative plasmids carrying no antibiotic resistance were transferred to Escherichia coli K-12. | 1983 | 6835408 |
| 4150 | 12 | 0.9999 | The worldwide emergence of plasmid-mediated quinolone resistance. Fluoroquinolone resistance is emerging in gram-negative pathogens worldwide. The traditional understanding that quinolone resistance is acquired only through mutation and transmitted only vertically does not entirely account for the relative ease with which resistance develops in exquisitely susceptible organisms, or for the very strong association between resistance to quinolones and to other agents. The recent discovery of plasmid-mediated horizontally transferable genes encoding quinolone resistance might shed light on these phenomena. The Qnr proteins, capable of protecting DNA gyrase from quinolones, have homologues in water-dwelling bacteria, and seem to have been in circulation for some time, having achieved global distribution in a variety of plasmid environments and bacterial genera. AAC(6')-Ib-cr, a variant aminoglycoside acetyltransferase capable of modifying ciprofloxacin and reducing its activity, seems to have emerged more recently, but might be even more prevalent than the Qnr proteins. Both mechanisms provide low-level quinolone resistance that facilitates the emergence of higher-level resistance in the presence of quinolones at therapeutic levels. Much remains to be understood about these genes, but their insidious promotion of substantial resistance, their horizontal spread, and their co-selection with other resistance elements indicate that a more cautious approach to quinolone use and a reconsideration of clinical breakpoints are needed. | 2006 | 17008172 |
| 4804 | 13 | 0.9999 | Mechanism of antimicrobial resistance and resistance transfer in anaerobic bacteria. The antimicrobial susceptibility pattern of anaerobic bacteria has been changing over the past decade. This paper reviews the mechanisms by which these organisms have become resistant to selected antibiotics and reviews data demonstrating that Bacteroides fragilis and Clostridium perfringens possess systems for transferring resistance determinants. Within bacteroides there is widespread resistance to penicillins, cephalosporins and tetracycline compounds while there have been reports of resistance to clindamycin and cefoxitin, and there is rare resistance reported for chloramphenicol and metronidazole. Transfer of resistance to penicillin, tetracycline and clindamycin has been demonstrated in bacteroides, while transfer of tetracycline resistance has been documented in clostridia. | 1982 | 6300995 |
| 4829 | 14 | 0.9998 | Diversity of the mechanisms of resistance to beta-lactam antibiotics. The sensitivity of a bacterium to beta-lactam antibiotics depends upon the interplay between 3 independent factors: the sensitivity of the essential penicillin-binding enzyme(s), the quantity and properties of the beta-lactamase(s) and the diffusion barrier that the outer-membrane of Gram-negative bacteria can represent. Those three factors can be modified by mutations or by the horizontal transfer of genes or portions of genes. | 1991 | 1961980 |
| 4143 | 15 | 0.9998 | Mobile genes coding for efflux-mediated antimicrobial resistance in Gram-positive and Gram-negative bacteria. Efflux mechanisms that account for resistance to a variety of antimicrobial agents are commonly found in a wide range of bacteria. Two major groups of efflux systems are known, specific exporters and transporters conferring multidrug resistance (MDR). The MDR systems are able to remove antimicrobials of different classes from the bacterial cell and occasionally play a role in the intrinsic resistance of some bacteria to certain antimicrobials. Their genes are commonly located on the bacterial chromosome. In contrast, the genes coding for specific efflux systems are often associated with mobile genetic elements which can easily be interchanged between bacteria. Specific efflux systems have mainly been identified with resistances to macrolides, lincosamides and/or streptogramins, tetracyclines, as well as chloramphenicol/florfenicol in Gram-positive and Gram-negative bacteria. In this review, we focus on the molecular biology of antimicrobial resistance mediated by specific efflux systems and highlight the association of the respective resistance genes with mobile genetic elements and their distribution across species and genus borders. | 2003 | 13678822 |
| 4326 | 16 | 0.9998 | Antibiotic resistance in oral/respiratory bacteria. In the last 20 years, changes in world technology have occurred which have allowed for the rapid transport of people, food, and goods. Unfortunately, antibiotic residues and antibiotic-resistant bacteria have been transported as well. Over the past 20 years, the rise in antibiotic-resistant gene carriage in virtually every species of bacteria, not just oral/respiratory bacteria, has been documented. In this review, the main mechanisms of resistance to the important antibiotics used for treatment of disease caused by oral/respiratory bacteria--including beta-lactams, tetracycline, and metronidazole--are discussed in detail. Mechanisms of resistance for macrolides, lincosamides, streptogramins, trimethoprim, sulfonamides, aminoglycosides, and chloramphenicol are also discussed, along with the possible role that mercury resistance may play in the bacterial ecology. | 1998 | 9825225 |
| 4152 | 17 | 0.9998 | Quinolone resistance: much more than predicted. Since quinolones are synthetic antibiotics, it was predicted that mutations in target genes would be the only mechanism through which resistance could be acquired, because there will not be quinolone-resistance genes in nature. Contrary to this prediction, a variety of elements ranging from efflux pumps, target-protecting proteins, and even quinolone-modifying enzymes have been shown to contribute to quinolone resistance. The finding of some of these elements in plasmids indicates that quinolone resistance can be transferable. As a result, there has been a developing interest on the reservoirs for quinolone-resistance genes and on the potential risks associated with the use of these antibiotics in non-clinical environments. As a matter of fact, plasmid-encoded, quinolone-resistance qnr genes originated in the chromosome of aquatic bacteria. Thus the use of quinolones in fish-farming might constitute a risk for the emergence of resistance. Failure to predict the development of quinolone resistance reinforces the need of taking into consideration the wide plasticity of biological systems for future predictions. This plasticity allows pathogens to deal with toxic compounds, including those with a synthetic origin as quinolones. | 2011 | 21687414 |
| 4473 | 18 | 0.9998 | The genetics of bacterial trimethoprim resistance in tropical areas. Resistance to trimethoprim in Gram-negative bacteria is largely manifested by two trimethoprim resistant dihydrofolate reductases (types I and II) encoded by genes originally located on resistance plasmids. Although trimethoprim resistance increased markedly after the clinical introduction of trimethoprim in the West, its spread has slowed and, in Edinburgh at least, has actually been declining. This reduction has been accompanied by the migration of a transposon, encoding the type I plasmid resistance gene, into the bacterial chromosome. In tropical areas, the incidence of trimethoprim resistance is very much higher. In Tanzania, it has spilled over into other bacteria outside the Enterobacteriaceae, but it was in India where the major problem existed. The majority (64%) of the Indian Enterobacteriaceae studied were resistant to the drug and most of the resistance genes were located on very large plasmids which also conferred resistance to many other antibacterial drugs. Some Indian plasmids carried a new trimethoprim resistance gene which is not detectable by conventional sensitivity tests and may be spreading unnoticed elsewhere. The proportion of trimethoprim resistance has been related to the volume of antibacterial drugs used. | 1987 | 3318025 |
| 4593 | 19 | 0.9998 | Origin, evolution and dissemination of antibiotic resistance genes. Comparison of resistance genes from different sources support the hypothesis that the antibiotic-producing microorganisms are the source of resistant determinants present in clinical isolates. There is also evidence that Gram-positive cocci (staphylococci and streptococci) can serve as a reservoir of resistance genes for Gram-negative bacteria. | 1987 | 2856426 |