Antimicrobial drug resistance: "prediction is very difficult, especially about the future" (1).Evolution of bacteria towards resistance to antimicrobial drugs, including multidrug resistance, is unavoidable because it represents a particular aspect of the general evolution of bacteria that is unstoppable. Therefore, the only means of dealing with this situation is to delay the emergence and subsequent dissemination of resistant bacteria or resistance genes. Resistance to antimicrobial drugs in bacteria can result from mutations in housekeeping structural or regulatory genes. Alternatively, resistance can result from the horizontal acquisition of foreign genetic information. The 2 phenomena are not mutually exclusive and can be associated in the emergence and more efficient spread of resistance. This review discusses the predictable future of the relationship between antimicrobial drugs and bacteria. ********** Over the last 60 years, bacteria and, in particular, those pathogenic for humans have evolved toward antimicrobial drug resistance. This evolution has 2 key steps: emergence and dissemination of resistance. Humans cannot affect emergence because it occurs by chance and represents a particular aspect of bacterial evolution. Emergence can result from mutations in housekeeping structural or regulatory genes or from acquiring foreign genetic information. However, much can be done to delay the subsequent spread of resistance. Dissemination can occur at the level of the bacteria (clonal spread), replicons (plasmid epidemics), or of the genes (transposons Transposons Types of transposable elements which comprise large discrete segments of deoxyribonucleic acid (DNA) capable of moving from one chromosome site to a new location. ). These 3 levels of dissemination, which coexist in nature, are not only infectious but also exponential, since all are associated with DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. duplication. Clonal dissemination is associated with chromosome replication, plasmid conjugation conjugation, in genetics conjugation, in genetics: see recombination. conjugation, in grammar conjugation: see inflection. with replicative transfer, and gene migration with replicative transposition (1). The spread of resistance has repeatedly been shown to be associated with antimicrobial drug use (2), which stresses the importance of the prudent use of these drugs; a notion reinforced by the observation that resistance is slowly reversible (3,4). Therefore, attempting to predict the future of the relationship between antimicrobial drugs and bacteria is conceptually challenging and potentially useful. For the sake of convenience, the examples will be taken mainly from the work carried out in the author's laboratory, although numerous other examples can be found in the literature. The clinically relevant predictable resistance types are listed in the Table. Although they have not yet been reported, they may exist in nature; their apparent absence is, at least for some of them, rather surprising. For example, streptococci Streptococcus (plural, streptococci) A genus of spherical-shaped anaerobic bacteria occurring in pairs or chains. Sydenham's chorea is considered a complication of a streptococcal throat infection. , including pneumococci and groups A, C, and G, can easily acquire in vitro conjugative plasmids from enterococci enterococci bacteria in the genus Enterococcus. and stably maintain and phenotypically express them (5). Therefore, it is all the more surprising that genes commonly found on plasmids in the latter bacterial genus, such as bla for penicillinase penicillinase /pen·i·cil·lin·ase/ (pen?i-sil´i-nas) a ß-lactamase preferentially cleaving penicillin. pen·i·cil·li·nase n. See beta-lactamase. production and aac6'-aph2" for resistance to nearly all commercially available aminoglycosides, have not yet emerged in streptococci. The situation is even more unusual for Listeria Listeria /Lis·te·ria/ (lis-ter´e-ah) a genus of gram-negative bacteria (family Corynebacterium); L. monocyto´genes causes listeriosis. Lis·te·ri·a n. spp., which remain susceptible to most antimicrobial drugs even though they can acquire plasmids from both enterococci and staphylococci (6). However, the obligate obligate /ob·li·gate/ (ob´li-gat) pertaining to or characterized by the ability to survive only in a particular environment or to assume only a particular role, as an obligate anaerobe. intracellular existence of Chlamydia chlamydia (kləmĭd`ēə), genus of microorganisms that cause a variety of diseases in humans and other animals. Psittacosis, or parrot fever, caused by the species Chlamydia psittaci, spp. likely protects them from contact with foreign DNA and accounts for their retained susceptibility to antimicrobial drugs. How To Anticipate Resistance One should distinguish "natural" antimicrobial drugs (e.g., kanamycin kanamycin /kan·a·my·cin/ (kan?ah-mi´sin) an aminoglycoside antibiotic derived from Streptomyces kanamyceticus, effective against aerobic gram-negative bacilli and some gram-positive bacteria, including mycobacteria; used as the ), which are produced by microorganisms from the environment, from semisynthetic semisynthetic /semi·syn·thet·ic/ (-sin-thet´ik) produced by chemical manipulation of naturally occurring substances. sem·i·syn·thet·ic adj. 1. (e.g., amikacin) and entirely synthetic compounds (e.g., quinolones), which are produced, at least in part, by humans. The microorganisms that produce natural antimicrobial drugs have to protect themselves from the products of their own secondary metabolism. To ensure their survival, these organisms have developed self-protection mechanisms similar to those found in resistant human pathogens (7); this observation led to the idea that the producers constitute the pool of origin of certain resistance genes (8). Therefore, the study of resistance in the strain used for the industrial production of an antimicrobial agent could allow a strong prediction about the mechanism that will be found later in bacteria pathogenic for humans. For example, the study of glycopeptide producers would have allowed the elucidation, long before it actually occurred, of the mechanism by which enterococci and, more recently, staphylococci could become resistant to these drugs (Figure 1). [FIGURE 1 OMITTED] As already noted, bacteria are resistant to antimicrobial drugs after horizontal DNA transfer or mutations. Thus, another prediction that can be made is that bacteria will transfer to susceptible species, resistance determinants already known in other bacterial genera, for example, the recent acquisition of glycopeptide resistance by Staphylococcus aureus from Enterococcus enterococcus /en·tero·coc·cus/ (en?ter-o-kok´us) pl. enterococ´ci an organism belonging to the genus Enterococcus. Enterococcus /En·tero·coc·cus/ ( spp. (9). However, this prediction is limited since it refers to mechanisms that have already been explained. In addition to being antimicrobial agent producers, the commensal commensal /com·men·sal/ (kom-men´sil) 1. living on or within another organism, and deriving benefit without harming or benefiting the host. 2. a parasite that causes no harm to the host. bacteria of mammals, particularly those in the gut, also represent a pool of origin for resistance genes. When infections are treated with an antimicrobial agent, all bacteria in the host are affected, including the commensal flora, which could result in the selection of resistant commensals, particularly in children who are administered oral antimicrobial drugs too frequently. Large numbers of these resident bacteria are present in the digestive tract where they are often in transient, but intimate, contact with exogenous microorganisms that are in various developmental states, including competence. These conditions favor the transfer of genes by transformation and by conjugation. Including antimicrobial drugs in animal feed also leads to the selection of a pool of resistance genes that can be transferred to commensal bacteria in the human digestive tract and thus ultimately to human pathogens, even when selective pressure is absent (10). In the case of mutations, predictions can be supported by 2 types of experimental approaches: in vivo with intact bacteria or in vitro by using DNA. Mutations resulting in resistance can be obtained in an accelerated fashion by using hypermutators, that is, bacteria deficient in the DNA repair system (11). Mutations are also accumulated by using continuous cultures, preferably in chemostats under suitable selective pressure. A similar enhanced rate of evolution can be obtained by (saturated) DNA mutagenesis mutagenesis /mu·ta·gen·e·sis/ (mu?tah-jen´e-sis) 1. the production of change. 2. the induction of genetic mutation. mu·ta·gen·e·sis n. pl. , followed by transformation into an appropriate host. This technique, for example, was used successfully to study the extent of variations in penicillinase genes that generate extended-spectrum [beta]-lactamase agents (12). Pathways to Resistance Modulation of Gene Expression In addition to developing mutations in structural genes for drug targets, bacteria can become resistant after mutational events in motifs for gene expression, such as promoters (13), in regulatory modules, such as 2-component regulatory systems (14), or positioning upstream from a gene of a mobile (15,16) or stable (17) promoter. Enhanced expression of genetic information can also be caused by alterations in translation attenuation Loss of signal power in a transmission. Attenuation The reduction in level of a transmitted quantity as a function of a parameter, usually distance. It is applied mainly to acoustic or electromagnetic waves and is expressed as the ratio of power densities. (18). The DNA regions involved in gene regulation are not always adjacent to the target gene. This factor makes finding regulatory mutations more complicated and makes detecting resistance by this mechanism generally impossible by genotypic techniques (19). Dissemination by Transformation Dissemination by transformation is more likely in spontaneously transformable bacterial species such as Streptococcus pneumoniae, Acinetobacter spp., and Neisseria spp. These bacteria can easily acquire, integrate, and express stretches of DNA. Since the latter can include portions of foreign chromosomes, this process renders chromosomal mutations infectious (20). Combination of Mechanisms Because of increased activity or the expanded spectrum of certain drug classes (e.g., [beta]-lactam agents and fluoroquinolones) or of local therapy (e.g., extremely high concentrations in the gut after oral administration of glycopeptides that do not cross the digestive barrier) bacteria need to combine mechanisms that confer resistance to the same class of molecules. This process is necessary to achieve high-level resistance (21) or expand the substrate range provided by a single resistance mechanism (22). An example is provided by gram-negative bacteria and [beta]-lactam agents. Extended-spectrum [beta]-lactamase agents are point mutants of "old" penicillinases (23). Generally, the biologic price to pay for extending the substrate range of this enzyme is hypersusceptibility to [beta]-lactamase inhibitors. However, the presence in certain enterobacteria en·ter·o·bac·te·ri·um n. pl. en·ter·o·bac·te·ri·a Any of various gram-negative rod-shaped bacteria of the family Enterobacteriaceae that includes some pathogens of plants and animals, such as the colon bacillus and salmonella. of the gene for a penicillinase on a small multicopy plasmid, which results in production of large amounts of the enzyme and confers resistance to [beta]-lactamase inhibitors by trapping (24). The net result of this combinatorial approach is the production of gram-negative bacteria that are resistant to all [beta]-lactam agents, except carbapenems and cephamycins, which are not substrates for the enzymes. Two Mechanisms Involved in Resistance Are Increasingly Frequent Impermeability im·per·me·a·ble adj. Impossible to permeate: an impermeable membrane; an impermeable border. im·per No antimicrobial agent is active against all bacteria. In fact, the intrinsic (natural) resistance of bacteria, which is better designated as insensitivity, defines the spectrum of activity of a drug, usually because the antimicrobial drug does not penetrate the bacteria. However, microorganisms can become resistant to nearly all drug classes, including those that act at the surface of the bacteria (e.g., [beta]-lactam agents, bacitracin bacitracin (băs'ĭtrā`sĭn), antibiotic produced by a strain of the bacterial species Bacillus subtilis. It is widely used for topical therapy such as for skin and eye infections; it is effective against gram-positive bacteria, ), by impermeability. This resistance can be secondary to 2 distinct pathways: passive, which involves alterations of outer membrane proteins, the porins, which decrease the rate of entry of antimicrobial drugs into the bacteria by diminution of the pore size (25), and active, which involves overexpression of an indigenous efflux efflux Medtalk That which flows outward pump that exports the antimicrobial drug outside the cell after a regulatory mutation (26). Trapping The mechanism of trapping, already mentioned in the case of resistance to [beta]-lactam agents by a combination of [beta]-lactamases, allows titration titration (tītrā`shən), gradual addition of an acidic solution to a basic solution or vice versa (see acids and bases); titrations are used to determine the concentration of acids or bases in solution. of the drugs, an alternative to impermeability, for lowering the intracellular concentrations of the antimicrobial drugs. This mechanism also works against aminoglycosides in bacteria that overproduce o·ver·pro·duce tr.v. o·ver·pro·duced, o·ver·pro·duc·ing, o·ver·pro·duc·es To produce in excess of need or demand. o an enzyme that has affinity for a drug they cannot inactivate in·ac·ti·vate v. 1. To render nonfunctional. 2. To make quiescent. in·ac  ti·va since it lacks the modification site (Figure 2)
(27,28). This mechanism has also been proposed to account for low-level
resistance to glycopeptides in staphylococci by overproducing target
sites in the outer layers of the peptidoglycan peptidoglycan /pep·ti·do·gly·can/ (pep?ti-do-gli´kan) a glycan (polysaccharide) attached to short cross-linked peptides; found in bacterial cell walls. pep·ti·do·gly·can n. ; thus, the antimicrobial drug does not reach the important target sites where the wall is assembled on the outer surface of the cytoplasmic cytoplasmic pertaining to or included in cytoplasm. cytoplasmic inclusions include secretory inclusions (enzymes, acids, proteins, mucosubstances), nutritive inclusions (glycogen, lipids), pigment granules (melanin, lipofuscin, membrane (29). [FIGURE 2 OMITTED] Prediction at the Genetic Level Genes from gram-positive cocci cocci /coc·ci/ (kok´si) plural of coccus. cocci [L.] plural of coccus. can be transferred by conjugation (of plasmids or transposons) not only among these microorganisms but also to gram-negative bacteria (30). The reverse is not true because of limitations in heterologous heterologous /het·er·ol·o·gous/ (het?er-ol´ah-gus) 1. made up of tissue not normal to the part. 2. xenogeneic. het·er·ol·o·gous adj. 1. gene expression. Consequently, one can confidently predict further dissemination of the resistance gene pool of gram-positive to gram-negative bacteria. We have been aware for a long period that "everything that exists in the universe is the result of chance and necessity" (Democritus, 460-370 BC), which holds true for antimicrobial drug resistance. Most unfortunately, and for various reasons, it is extremely difficult to think like a bacterium. In other words Adv. 1. in other words - otherwise stated; "in other words, we are broke" put differently , predicting the emergence of resistance to a drug class by a precise molecular mechanism is nearly impossible (e.g., glycopeptide resistance in enterococci or plasmid-mediated resistance to fluoroquinolones). We also cannot anticipate, among all the conceivable mechanisms of resistance (31), which will emerge first under natural conditions. However, based on the understanding during recent decades of the physiology (genetics and biochemistry) of bacterial resistance to antimicrobial drugs, impressive progress has been made in the techniques for in vitro detection and for elucidation of resistance. This progress should, in turn, be helpful in delaying the second step of resistance: dissemination. Acknowledgments I thank N. Bohr for providing the title, V. Loncle-Provot for inspiring me to write this review, and M.H. Saier for providing laboratory facilities. This article is dedicated to the memory of my colleague and friend Maurice Hofnung. References (l.) Courvalin P, Trieu-Cuot R Minimizing potential resistance: the molecular view. Clin Infect Dis. 2001;33:S138-46. (2.) Seppala H, Klaukka T, Lehtonen R, Nenonen E, Huovinen P. Outpatient use of erythromycin erythromycin (ĭrĭth'rōmī`sĭn), any of several related antibiotic drugs produced by bacteria of the genus Streptomyces (see antibiotic). : link to increased erythromycin resistance in group A streptococci. Clin Infect Dis. 1995;21:1378-85. (3.) Andersson DI. Persistence of antibiotic resistant bacteria. Curr Opin Microbiol. 2003;6:452-6. (4.) Chiew YF, Yeo SF, Hall LM, Livermore DM. Can susceptibility to an antimicrobial be restored by halting its use? The case of streptomycin streptomycin (strĕp'tōmī`sĭn), antibiotic produced by soil bacteria of the genus Streptomyces and active against both gram-positive and gram-negative bacteria (see Gram's stain), including species resistant to other versus Enterobacteriaceae. J Antimicrob Chemother. 1998;41:247-51. (5.) Macrina FL, Archer GL. Conjugation and broad host range plasmids in streptococci and staphylococci. In: Clewell DB, editor. Bacterial conjugation. New York, London: Plenun Press; 1993. p. 313-29. (6.) Charpentier E, Courvalin P. Antibiotic resistance in Listeria spp. Antimicrob Agents Chemother. 1999;43:2103-8. (7.) Mazodier P, Davies J. Gene transfer between distantly related bacteria. Annu Rev Genet. 1991;25:147-74. (8.) Walker MS, Walker JB. Streptomycin biosynthesis Biosynthesis The synthesis of more complex molecules from simpler ones in cells by a series of reactions mediated by enzymes. The overall economy and survival of the cell is governed by the interplay between the energy gained from the breakdown of compounds and metabolism. J Biol Chem. 1970;245:6683-9. (9.) Weigel LM, Clewell DB, Gill SR, Clark NC, McDougal LK, Flannagan SE, et al. Genetic analysis of a high-level vancomycin-resistant isolate of Staphylococcus aureus. Science. 2003;302:1569-71. (10.) Moubareck C, Bourgeois N, Courvalin P, Doucet-Populaire F. Multiple antibiotic resistance gene transfer from animal to human enterococci in the digestive tract of gnotobiotic gno·to·bi·ot·ic adj. 1. Of or relating to gnotobiology. 2. Free of germs or associated only with known or specified germs. gnotobiotic pertaining to a gnotobiote or to gnotobiotics. mice. Antimicrob Agents Chemother. 2003;47:2993-6. (11.) Taddei F, Matic I, Godelle B, Radman M. To be a mutator A mutator may refer to:
(12.) Petrosino J, Cantu III C, Palzkill T. [beta]-Lactamases: protein evolution in real time. Trends Microbiol 1998;6:323-7. (13.) Chen ST, Clowes RC. Variations between the nucleotide sequences of Tn1, Tn2, and Tn3 and expression of [beta]-lactamase in Pseudomonas aeruginosa and Escherichia coli. J Bacteriol. 1987;169:913-6. (14.) Baptista M., Depardieu F, Reynolds P, Courvalin P, Arthur M. Mutations leading to increased levels of resistance to glycopeptide antibiotics in VanB-type enterococci. Mol Microbiol. 1997;25:93-105. (15.) Goussard S, Sougakoff W, Mabilat C, Bauernfeind A, Courvalin P. An IS1-like element is responsible for high-level synthesis of extended-spectrum [beta]-lactamase TEM-6 in Enterobacteriaceae. J Gen Microbiol. 1991;137:2681-7. (16.) Rudant E, Courvalin P, Lambert T. Characterization of IS18, an element capable of activating the silent aac(6')-Ij gene of Acinetobacter sp. 13 strain BM2716 by transposition transposition /trans·po·si·tion/ (trans?po-zish´un) 1. displacement of a viscus to the opposite side. 2. . Antimicrob Agents Chemother. 1998;42:2759-61. (17.) Magnet S, Courvalin P, Lambert T. Activation of the cryptic aac(6')-Iy aminoglycoside aminoglycoside /ami·no·gly·co·side/ (-gli´ko-sid) any of a group of antibacterial antibiotics (e.g., streptomycin, gentamicin) derived from various species of Streptomyces resistance gene of Salmonella by a chromosomal deletion generating a transcriptional fusion. J Bacteriol. 1999,181:6650-5. (18.) Leclercq R, Courvalin P. Resistance to macrolides and related antibiotics in Streptococcus pneumoniae. Antimicrob Agents Chemother. 2002;46:2727-34. (19.) Courvalin P. Genotypic approach to the study of bacterial resistance to antibiotics. Antimicrob Agents Chemother. 1991;35:1019-23. (20.) Ferrandiz MJ, Fenoll A, Linares J, de la Campa AG. Horizontal transfer of parC and gyrA in fluoroquinolone-resistant clinical isolates of Streptococcus pneumoniae. Antimicrob Agents Chemother. 2000;44:840-7. (21.) Arthur M, Courvalin P. Contribution of two different mechanisms to erythromycin resistance in Escherichia coli. Antimicrob Agents Chemother. 1986;30:694-700. (22.) Ferretti JJ, Gilmore KS, Courvalin P. Nucleotide sequence analysis of the bifunctional bi·func·tion·al adj. 1. Having two functions: bifunctional neurons. 2. Chemistry Having or involving two functional groups or binding sites: 6'-aminoglycoside acetyltransferase, 2"-aminoglycoside phosphotransferase determinant from Streptococcus streptococcus (strĕp'təkŏk`əs), any of a group of gram-positive bacteria, genus Streptococcus, some of which cause disease. faecalis: identification and cloning of gene regions specifying the two activities. J Bacteriol. 1986;167:631-8. (23.) Sougakoff W, Goussard S, Gerbaud G, Courvalin P. Plasmid-mediated resistance to third-generation cephalosporins Cephalosporins Definition Cephalosporins are medicines that kill bacteria or prevent their growth. Purpose Cephalosporins are used to treat infections in different parts of the body—the ears, nose, throat, lungs, sinuses, and caused by point-mutations in TEM-type penicillinase genes. Rev Infect Dis. 1988;10:879-84. (24.) Mabilat C, Courvalin P. Development of "oligotyping" for characterization and molecular epidemiology of TEM TEM 1. transmission electron microscope. 2. triethylenemelamine. 3. transmissible encephalopathy of mink. [beta]-lactamases in members of the family Enterobacteriaceae. Antimicrob Agents Chemother. 1990;34:2210-6. (25.) Nikaido H. Molecular basis of bacterial outer membrane permeability revisited. Microbiol Mol Biol Rev. 2003;67:593-656. (26.) Li XZ, Nikaido H. Efflux-mediated drug resistance in bacteria. Drugs. 2004;64:159-204. (27.) Menard R, Molinas C, Arthur M, Duval J, Courvalin P, Leclercq R. Overproduction o·ver·pro·duce tr.v. o·ver·pro·duced, o·ver·pro·duc·ing, o·ver·pro·duc·es To produce in excess of need or demand. o of 3'-aminoglycoside phosphotransferase type I confers resistance to tobramycin tobramycin /to·bra·my·cin/ (to?brah-mi´sin) an aminoglycoside antibiotic derived from a complex produced by Streptomyces tenebrarius, in Escherichia coli. Antimicrob Agents Chemother. 1993;37:78-83. (28.) Magnet S, Smith TA, Zheng R, Nordmann P, Blanchard JS. Aminoglycoside resistance resulting from tight drug binding to an altered aminoglycoside acetyltransferase. Antimicrob Agents Chemother. 2003;47:1577-83. (29.) Srinivasan A, Dick JD, Perl TM. Vancomycin resistance in staphylococci. Clin Microbiol Rev. 2002;15:430-8. (30.) Courvalin R Transfer of antibiotic resistance genes between gram-positive and gram-negative bacteria. Antimicrob Agents Chemother. 1994;38:1447-51. (31.) Quintiliani Jr R, Sahm D, Courvalin P. Mechanisms of resistance to antimicrobial agents. In Murray PR, Baron EJ, Pfaller MA, Tenover FC, Yolken RH, editors. Manual of clinical microbiology. 7th ed. Washington: American Society for Microbiology The American Society for Microbiology (ASM) is a scientific organization, based in the United States although with over 43,000 members throughout the world. It is the largest single life science professional organization and its members include those whose interests encompass basic ; 1998. p. 1505-25. (32.) Pootoolal J, Thomas MG, Marshall CG, Neu JM, Hubbard BK, Walsh CT, et al. Assembling the glycopeptide antibiotic scaffold: the biosynthesis of A47934 from Streptomyces Streptomyces (strĕp'təmī`sēz), bacterial genus of the order Actinomycetales, members of which resemble fungi in their branching filamentous structure. Various species produce such antibiotics as streptomycin and various tetracyclines. toyocaensis NRRL NRRL Norsk Radio Relae Liga (Norwegian: Norwegian Radio Relay League; Norway) 15009. Proc Natl Acad Sci U S A. 2002;99:8962-7. (33.) Arthur M, Molinas C, Depardieu F, Courvalin P. Characterization of Tn1546, a Tn3-related transposon transposon /trans·po·son/ (trans-po´zon) a small mobile genetic (DNA) element that moves around the genome or to other genomes within the same cell, usually by copying itself to a second site but sometimes by splicing itself out of its conferring glycopeptide resistance by synthesis of depsipeptide peptidoglycan precursors in Enterococcus faecium BM4147. J Bacteriol. 1993;175:117-27. (1) Niels Bohr. Patrice Courvalin, Institut Pasteur, Paris, France Dr Courvalin is a professor at the Institut Pasteur, where he directs the French National Reference Center for Antibiotics and is the head of the Antibacterial Agents Unit. He specializes in the genetics and biochemistry of antimicrobial drug resistance. Address for correspondence: Patrice Courvalin, Unite des Agents Antibacteriens, Institut Pasteur, 75015 Paris, France; fax: 00-1-45-68-83-19; email: pcourval@pasteur.fr
Table. Predictable resistance types
Resistance phenotype or
Organism mechanism
Streptococcus pneumoniae Penicillinase, gentamicin,
glycopeptides
Streptococcus groups Penicillins
A, C, G
Listeria monocytogenes Penicillins, gentamicin
Legionella pneumophila Macrolides, fluoroquinolones
Salmonella enterica Third-generation cephalosporins
serovar
Typhi
Haemophilus influenzae Third-generation cephalosporins
Neisseria meningitidis Third-generation cephalosporins
Brucella spp. Tetracyclines, rifampin,
streptomycin
Clostridium difficile Glycopeptides
C. perfringens Penicillinase
Chlamydia spp. Tetracyclines
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