Role of beta-lactamases and outer membrane proteins in multiple beta-lactam resistance of Enterobacter cloacae

Beta-lactam antibiotics: from antibiosis to resistance and bacteriology

This review focuses on the era of antibiosis that led to a better understanding of bacterial morphology, in particular the cell wall component peptidoglycan. This is an effort to take readers on a tour de force from the concept of antibiosis, to the serendipity of antibiotics, evolution of beta-lactam development, and the molecular biology of antibiotic resistance. These areas of research have culminated in a deeper understanding of microbiology, particularly in the area of bacterial cell wall synthesis and recycling. In spite of this knowledge, which has enabled design of new even more effective therapeutics to combat bacterial infection and has provided new research tools, antibiotic resistance remains a worldwide health care problem.

Molecular basis of bacterial outer membrane permeability revisited

Gram-negative bacteria characteristically are surrounded by an additional membrane layer, the outer membrane. Although outer membrane components often play important roles in the interaction of symbiotic or pathogenic bacteria with their host organisms, the major role of this membrane must usually be to serve as a permeability barrier to prevent the entry of noxious compounds and at the same time to allow the influx of nutrient molecules. This review summarizes the development in the field since our previous review (H. Nikaido and M. Vaara, Microbiol. Rev. 49:1-32, 1985) was published. With the discovery of protein channels, structural knowledge enables us to understand in molecular detail how porins, specific channels, TonB-linked receptors, and other proteins function. We are now beginning to see how the export of large proteins occurs across the outer membrane. With our knowledge of the lipopolysaccharide-phospholipid asymmetric bilayer of the outer membrane, we are finally beginning to understand how this bilayer can retard the entry of lipophilic compounds, owing to our increasing knowledge about the chemistry of lipopolysaccharide from diverse organisms and the way in which lipopolysaccharide structure is modified by environmental conditions.

Characterization of IMI-1 beta-lactamase, a class A carbapenem-hydrolyzing enzyme from Enterobacter cloacae

In 1984, a year prior to the U.S. approval of imipenem for clinical use, a wound isolate and a bile isolate of Enterobacter cloacae were obtained from two patients in a California hospital. These isolates were resistant to imipenem, penicillins, and inhibitor combinations; early cephalosporins such as cephalothin, cefamandole, and cefoxitin; and cefoperazone. However, they were susceptible (MICs, < 4 micrograms/ml) to cefotaxime, ceftriaxone, ceftazidime, and moxalactam. Both strains produced an apparent TEM-1 beta-lactamase; an inducible NmcA-type imipenem-hydrolyzing beta-lactamase, IMI-1, with a pl of 7.05; and an inducible beta-lactamase with a pI of 8.1, typical of an E. cloacae AmpC beta-lactamase. Purified IMI-1 hydrolyzed imipenem and benzylpenicillin at modest rates, but more slowly than cephaloridine. The enzyme was inhibited by clavulanic acid and tazobactam. EDTA did not inhibit the cephaloridine-hydrolyzing activity. The beta-lactamase gene encoding IMI-1, imiA1, was cloned from E. cloacae 1413B. Sequence analysis identified the imiA1 gene as encoding a class A serine beta-lactamase. Both the imiA1 DNA and encoded amino acid sequences shared greater than 95% identity with the NmcA gene and its encoded protein. DNA sequence analysis also identified a gene upstream of imiA1 that shares > 95% identity with nmcR and that may encode a regulatory protein. In conclusion, IMI-1, a carbapenem-hydrolyzing beta-lactamase inhibited by clavulanic acid, was identified as a group 2f, class A, carbapenem-hydrolyzing cephalosporinase.

Relative importances of outer membrane permeability and group 1 beta-lactamase as determinants of meropenem and imipenem activities against Enterobacter cloacae

The roles of outer membrane permeability and Bush group 1 beta-lactamase activity in determining Enterobacter cloacae susceptibility to either meropenem or imipenem were investigated. A beta-lactamase-deficient strain was obtained by mutagenesis from a clinical isolate of E. cloacae, and a porin-deficient strain was selected from this mutant with cefoxitin. Both strains were transformed with the plasmid pAA20R, which contained the gene coding for the carbapenem-hydrolyzing CphA beta-lactamase, and the carbapenem permeability coefficients were measured by the Zimmermann and Rosselet technique (W. Zimmermann and A. Rosselet, Antimicrob. Agents Chemother. 12:368-372, 1977). The permeability coefficient of meropenem was roughly half that of imipenem in the normally permeable strain and almost seven times lower than that of imipenem in the porin-deficient strain. In the porin-deficient strain, the virtual absence of porins caused the MICs of meropenem to increase from 8 to 16 times, while it did not affect the MICs of imipenem. Conversely, the beta-lactamase affected imipenem but not meropenem activity: meropenem showed a similar activity in the parent strain and in the beta-lactamase-deficient mutant with both a low- and high-density inoculum, whereas imipenem was 16 times less active against the parent strain when the high-density inoculum was used. It is concluded that outer membrane permeability and stability to group 1 beta-lactamase have different impacts on the activities of meropenem and imipenem against E. cloacae.

AmpG, a signal transducer in chromosomal beta-lactamase induction

The chromosomal ampC beta-lactamase in Citrobacter freundii and Enterobacter cloacae is inducible by beta-lactam antibiotics. When an inducible ampC gene is introduced on a plasmid into Escherichia coli together with its transcriptional regulator ampR, the plasmid-borne beta-lactamase is still inducible. We have isolated mutants, containing alterations in a novel E. coli gene, ampG, in which a cloned C. freundii ampC gene is unable to respond to beta-lactam inducers. The ampG gene was cloned, sequenced and mapped to minute 9.6 on the E. coli chromosome. The deduced amino acid sequence predicted AmpG to be a 53 kDa, transmembrane protein, which we propose acts as a signal transducer or permease in the beta-lactamase induction system. Immediately upstream of ampG there is another 579-base-pair-long open reading frame (ORF) encoding a putative lipoprotein shown to be non-essential for beta-lactamase induction. We have found that ampG and this ORF form an operon, whose promoter is located in front of the ORF. Located closely upstream of the putative promoter is the morphogene bolA, which is transcribed in the opposite orientation. However, using transcription fusions, we have found that the ampG transcription is not regulated by bolA. In addition, we show that transcription is probably not regulated by either the starvation specific sigma factor RpoS, which controls bolA, or by AmpD the negative regulator for ampC transcription.

Imipenem resistance in Enterobacter

Blood cultures obtained on two separate occasions from a 37-year-old male who received multiple antibiotics (including imipenem) for treatment of repeated episodes of intraabdominal abscesses and bacteremia yielded two isolates of Enterobacter with reduced susceptibility to imipenem, extended-spectrum cephalosporins, penicillins and aztreonam. Both isolates were unstable, giving rise to different colony types, each of which produced a single, non-inducible Bush group 1 beta-lactamase (pI = 9.6) that hydrolyzed imipenem. Outer membrane proteins were analyzed but no differences were detected between strains with different levels of imipenem resistance. Three-dimensional tests performed in conjunction with disk diffusion susceptibility tests provided a rapid and convenient means of detecting the production of imipenem-hydrolyzing enzymes by the Enterobacter strains. These isolates provided additional evidence that overproduction of the group 1 cephalosporinase of Enterobacter can contribute to resistance to imipenem.

High specificity of cphA-encoded metallo-beta-lactamase from Aeromonas hydrophila AE036 for carbapenems and its contribution to beta-lactam resistance

The Aeromonas hydrophila AE036 chromosome contains a cphA gene encoding a metallo-beta-lactamase highly active against carbapenem antibiotics. This enzyme was induced in strain AE036 to the same extent by both benzylpenicillin and imipenem. When the cphA gene was inserted into plasmid pACYC184, used to transform Escherichia coli DH5 alpha, the MICs of imipenem, meropenem, and penem HRE664 for recombinant clone DH5 alpha(pAA20R), expressing the Aeromonas metallo-beta-lactamase, were significantly increased, but those of penicillins and cephalosporins were not. When the metallo-beta-lactamase purified from E. coli DH5 alpha(pAA20R) was assayed with several beta-lactam substrates, it hydrolyzed carbapenems but not penicillins or cephalosporins efficiently. These results demonstrate that this metallo-beta-lactamase possesses an unusual spectrum of activity compared with all the other class B enzymes identified so far, being active on penems and carbapenems only. This enzyme may thus contribute to the development of resistance to penems and carbapenems but not other beta-lactams.

Imipenem- and meropenem-resistant mutants of Enterobacter cloacae and Proteus rettgeri lack porins

Carbapenems such as imipenem and meropenem are not rapidly hydrolyzed by commonly occurring beta-lactamases. Nevertheless, it was possible, by mutagenesis and selection, to isolate mutant strains of Enterobacter cloacae and Proteus rettgeri that are highly resistant to meropenem and imipenem. Two alterations were noted in the E. cloacae mutants. First, the mutant strains appeared to be strongly derepressed in the production of beta-lactamases, which reached a very high level when the strains were grown in the presence of imipenem. Second, these mutants were deficient in the production of nonspecific porins, as judged by the pattern of outer membrane proteins as well as by reconstitution assays of permeability. As with most porin-deficient mutants, their cultures were unstable, and their cultivation in the absence of carbapenems rapidly led to an overgrowth of porin-producing revertants. Analysis of the data suggests that the synergism between the lowered outer membrane permeability and the slow but significant hydrolysis of carbapenems by the overproduced enzymes can explain the resistance phenotypes quantitatively, although the possibility of alteration of the target cannot be excluded at present. With P. rettgeri mutants, there was no indication of further derepression of beta-lactamase, but the enzyme hydrolyzed imipenem much more efficiently than the E. cloacae enzyme did. In addition, the major porin was absent in one mutant strain. These results suggest that a major factor for the carbapenem resistance of these enteric bacteria is the porin deficiency, and this conclusion forms a contrast to the situation in Pseudomonas aeruginosa, in which the most prevalent class of imipenem-resistant mutants appears to lack the specific channel protein D2 yet retains the major nonspecific porin F.

State of penicillin-binding proteins and requirements for their bactericidal interaction with beta-lactam antibiotics in Serratia marcescens highly resistant to extended-spectrum beta-lactams

The quantities of penicillin-binding proteins (PBPs), and sensitivity to extended-spectrum beta-lactams, were measured in isogenic strains of Serratia marcescens with high (HR) and low (LR) resistance to extended-spectrum beta-lactam antibiotics and with constitutively overproduced chromosomal beta-lactamase in the periplasm. The binding of structurally different beta-lactams to PBPs in growing resistant bacteria was determined quantitatively. In S. marcescens HR, the amounts of PBPs 3 and 6 were, respectively, 1.5 and 2 times those in strain LR and in sensitive reference strains. Sensitivities of the essential PBPs in S. marcescens LR and HR to the tested beta-lactams were identical. Only a single target, PBP 3, was highly sensitive to cefotaxime, ceftazidime and aztreonam. In contrast, three PBPs (2, 1A and 3) were highly sensitive to imipenem. In growing S. marcescens HR and LR, all antibiotics, even at fractions of their minimal growth inhibitory concentrations (MICs), bound extensively to those PBPs which were highly sensitive to them. Thus, overproduced beta-lactamase did not prevent PBP-beta-lactam interaction. Only at or above their (high) MICs did cefotaxime, ceftazidime and aztreonam bind to multiple targets. Growth inhibition of the otherwise highly resistant S. marcescens HR at the lower MIC of imipenem was correlated with the binding of this antibiotic to multiple, highly sensitive targets in the bacteria. Killing of the bacteria by inactivation of multiple targets was suggested. This assumption was supported by the synergistic killing of HR bacteria by combinations of the PBP-2-specific mecillinam with PBP-3-specific beta-lactams.

Reevaluation of the factors involved in the efficacy of new beta-lactams against Enterobacter cloacae

The roles of outer membrane permeability, beta-lactamase stability, and inhibition of penicillin-binding proteins in the activity of new beta-lactams against Enterobacter cloacae were reappraised by using several methodological improvements. Outer membrane permeability in intact cells was determined by using a high-pressure liquid chromatography (HPLC)-based technique that avoided certain possible artifacts of the traditional methods. Vmax values were calculated from the numbers of enzyme molecules produced per cell and from catalytic constant (Kcat) values, which were obtained with purified beta-lactamase. Minimal periplasmic antibiotic concentrations needed to inhibit bacterial cell wall synthesis were estimated from the Zimmermann-Rosselet equation. All the beta-lactams tested formed relatively stable complexes with purified beta-lactamase. The antibiotics that exhibited low affinity for beta-lactamase apparently needed higher periplasmic concentrations to inhibit cell wall synthesis, suggesting a possible correlation between the affinity of beta-lactamase and the affinity of penicillin-binding proteins for the new beta-lactams. By using these estimates of outer membrane permeability, beta-lactamase hydrolysis, and cell wall-inhibiting concentrations, MIC could be theoretically predicted to within 1 dilution for five beta-lactams in three isogenic E. cloacae strains with differences in antibiotic susceptibility due to different porin or beta-lactamase contents.

Isolation of Enterobacter aerogenes susceptible to beta-lactam antibiotics despite high level beta-lactamase production

This report describes a patient with nosocomial meningitis from whom four distinct isolates of Enterobacter aerogenes were recovered over a complicated course of chemotherapy. The initial isolate was susceptible to expanded spectrum beta-lactams despite constitutive production of high levels of beta-lactamase. Resistant isolates recovered during antibiotic therapy had lost a 42,000 outer membrane protein. These data suggest that b-lactam susceptibility in the original isolate was due to "hyperpermeability" mediated by the 42,000 Dalton protein.

Molecular characterization of an Enterobacter cloacae gene (romA) which pleiotropically inhibits the expression of Escherichia coli outer membrane proteins

The introduction of a newly cloned Enterobacter cloacae chromosomal gene romA, into Escherichia coli and E. cloacae resulted in enhancement of resistance to quinolones, beta-lactams, chloramphenicol, and tetracycline. The primary effect of romA on a multicopy vector in E. coli was almost complete inhibition of OmpF expression in the outer membrane. From the experiments with ompR and envZ mutants or with ompF-lacZ and ompC-lacZ fusion plasmids, it was concluded that this inhibition is posttranscriptional. The introduction of romA on a multicopy vector into strains with micF deletion elicited only a moderate decrease in OmpF protein expression. This indicates that reduction of OmpF expression by romA is partly mediated posttranscriptionally by the activation of micF. Moreover, the overexpression of RomA protein from an isopropyl-beta-D-thiogalactopyranoside (IPTG)-inducible promoter resulted in nearly complete inhibition of expression of OmpC and OmpA, as well as OmpF. Taken together with an observation in a recent study that overexpressed OmpC inhibited the synthesis of OmpA and LamB, a possible inhibitory mechanism at the translational stage of the synthesis of outer membrane proteins should also be considered. By Southern hybridization, romA was generally detected in the chromosomes of all E. cloacae strains tested but not in the E. coli K-12 chromosome. Sequence data show that there is an open reading frame specifying 368 amino acids residues including a putative signal peptide. RomA appears to belong to the outer membrane protein family since it was extractable from an outer membrane preparation, but no sequence homology to other outer membrane proteins was detected.

ampG is essential for high-level expression of AmpC beta-lactamase in Enterobacter cloacae

Mutants of Enterobacter cloacae 55 were studied to delineate more completely the genetics of inducible expression of AmpC beta-lactamase. E. cloacae 55M-L, derived by mutagenesis from a mutant with high-level cefotaxime resistance (MIC, greater than 64 micrograms/ml), E. cloacae 55M, demonstrated a novel phenotype by producing only low levels of AmpC constitutively. Neither the parental phenotype of E. cloacae 55M nor the wild-type phenotype of E. cloacae 55 could be restored in E. cloacae 55M-L by the introduction of functional ampR, ampC, or ampD genes. Cloning each of these genes from E. cloacae 55M-L confirmed the same genotype for this mutant as for its parental strain. Mutation of E. cloacae 55M-L to the E. cloacae 55M phenotype was found to occur spontaneously at a frequency of 10(-8). All such revertants demonstrated an inducible wild-type phenotype after introduction of a functional ampD. These results suggested that the E. cloacae 55M-L phenotype was due to a mutation in an as yet unrecognized gene, designated ampG. Verification of this gene was obtained by the restoration of the E. cloacae 55M phenotype in E. cloacae 55M-L by introduction of a cloned 2.9-kilobase BamHI fragment from the E. cloacae 55 chromosome. Transformation of both ampG and ampD into E. cloacae 55M-L reconstituted the inducible wild-type phenotype. These results indicate that ampG is required for the activation of ampC by AmpR. Without ampG, neither induction nor high-level expression of AmpC is possible. It is likely that the ampG gene product and AmpD together modulate the ability of AmpR to activate ampC expression.

Purification of a class C A-type beta-lactamase from a derepressed strain of Enterobacter cloacae. Comparison of the wild-type and mutant enzyme with those from strains P99, 208 and GN7471

Enterobacter cloacae strain 5822 expresses low levels of a class C beta-lactamase which can be induced 100-fold by imipenem. Mutants that constitutively express high levels of beta-lactamase can be selected on aztreonam or cefotaxime. The beta-lactamase from one such mutant (5822M2) has been purified to homogeneity and compared on the basis of subunit Mr, pI, substrate specificity, inhibitor sensitivity and immunological cross-reactivity with the enzyme from strains P99, GN7471 and 208, which have been studied previously. The enzyme from strain 5822M2 is clearly related to these other forms and is of the A-type according to the criteria of Seeberg, Tolxdorff-Neutzling & Wiedemann [Antimicrob. Agents Chemother. (1983) 23, 918-925]. The enzyme from the wild-type strain (5822) is shown to be identical to that found in the depressed strain (5822M2), indicating that the mutation is in a regulatory gene. A detailed analysis of the kinetics of the enzyme from strain 5822M2 shows that all of the beta-lactams studied are substrates and that a mechanism involving the formation of an acyl-enzyme is probably applicable in every case. The substrates however can clearly be grouped into two classes, i.e. 'good' substrates with kcat. values of 80-1200 s-1 and 'poor' substrates/good inhibitors with kcat. values of 0.009-0.00007 s-1. The permeability barrier to aztreonam is 4-fold less in the derepressed strain when compared with the wild-type strain. This is associated with significant changes in the expression of outer membrane porins. The observed resistance in the derepressed mutant appears to be linked to the elevated levels of beta-lactamase (3000-fold) rather than to the modest changes in the permeability barrier.

Effects of beta-lactamases and omp mutation on susceptibility to beta-lactam antibiotics in Escherichia coli

Four types of beta-lactamases consisting of a penicillinase type I (TEM-1), a penicillinase type II (OXA-1), a cephalosporinase of Citrobacter freundii, and a cephalosporinase of Proteus vulgaris were introduced into Escherichia coli MC4100 and its omp mutants, MH1160 (MC4100 ompR1) and MH760 (MC4100 ompR2), by transformation. Effects of the combination of the omp mutations and these beta-lactamases on the susceptibility of E. coli strains were studied with 15 beta-lactam antibiotics including cephalosporins, cephamycins, penicillins, imipenem, and aztreonam. The ompR1 mutant, MH1160, lacks OmpF and OmpC, and it showed reduced susceptibility to 11 of the 15 beta-lactam agents. The reduction in susceptibility to cefoxitin, moxalactam, and flomoxef was much greater than reduction in susceptibility to the other agents. When the ompR1 mutant produced the cephalosporinase of C. freundii, the susceptibility of the mutant to 12 of the 15 beta-lactam antibiotics decreased. The reduction in susceptibility of MH1160 to 10 of the 12 agents affected by the enzyme was two- to fourfold greater than that observed in MC4100. Such a synergistic effect was also observed with the cephalosporinase of P. vulgaris and ompR1 mutation against six cephalosporins, moxalactam, and aztreonam.

Mechanism of action of cephalosporins and resistance caused by decreased affinity for penicillin-binding proteins in Bacteroides fragilis

The susceptibilities of 52 clinical isolates of Bacteroides fragilis to five monoanionic cephalosporins were examined. Cefoperazone showed the highest antibacterial activity, followed by ceftezole, cefazolin, cefamandole, and cephalothin. There were two groups of resistant strains: one group (ca. 15%), of which B. fragilis G-232 was a typical sample, was resistant to ceftezole (MIC, 100 micrograms/ml), cefazolin (MIC, 100 micrograms/ml), and cephalothin (MIC, 200 micrograms/ml) but not cefoperazone (MIC, 6.25 micrograms/ml) or cefamandole (MIC, 25 micrograms/ml). On the basis of studies of stability to beta-lactamase, outer membrane permeation, and affinity for penicillin-binding proteins (PBPs), we conclude that decreased affinity for PBP 3 may play an important role in the resistance to ceftezole, cefazolin, and cephalothin in B. fragilis G-232. Another group (also ca. 15%), of which B. fragilis G-242 was a representative, was resistant to all five cephalosporins (MIC, 100 to 400 micrograms/ml) and produced a high amount of beta-lactamase. Similar broad-spectrum resistance was seen in a mutant of strain G-232 that had a greater-than-30-fold increase in beta-lactamase production.

Do antibiotic combinations prevent the emergence of resistant organisms?

Antibiotic combinations are often used in the therapy of infectious diseases to broaden the antibacterial spectrum and to enhance antimicrobial activity. Another potential reason for combination therapy is to reduce or prevent the emergence of resistant organisms during therapy. Antituberculous chemotherapy provides a classic example in which drug combinations have successfully prevented the emergence of drug-resistant organisms and improved clinical outcome. The purpose of this brief report is to review the success of combination therapy in preventing resistance in more common bacterial infections.

The emergence of resistance during single-drug therapy is a well-documented clinical phenomenon, especially with the broad-spectrum ß-lactams against gram-negative bacilli. As with Mycobacterium tuberculosis, the resistant organisms are generally thought to be naturally occurring mutants selected by drug exposure. Because mutation frequencies appear to vary from 10-6 to 10-8, it is not surprising that emergence of resistant organisms observed clinically occurs primarily at sites of high organism density, such as the respiratory and urinary tracts.

Resistance to ticarcillin-potassium clavulanate among clinical isolates of the family Enterobacteriaceae: role of PSE-1 beta-lactamase and high levels of TEM-1 and SHV-1 and problems with false susceptibility in disk diffusion tests

Thirty-four clinical isolates of the family Enterobacteriaceae from the University of Texas M. D. Anderson Cancer Center appeared resistant to ticarcillin-potassium clavulanate in agar dilution and broth macrodilution tests. Among those isolates producing a single non-class I beta-lactamase, resistance was due to production of high levels of TEM-1, SHV-1, or class IV enzymes. In five Escherichia coli isolates, production of low levels of PSE-1 was responsible for resistance which seemed due to rapid hydrolysis of ticarcillin rather than diminished susceptibility of PSE-1 to inhibition by potassium clavulanate. Comparisons of dilution and disk diffusion tests revealed major discrepancies, with 65% false susceptibility in the disk test. Revision of the interpretive criteria used for disk diffusion tests from less than or equal to 11 to less than or equal to 18 mm for resistance is proposed to resolve these discrepancies until clinical data are obtained which can be used to determine which in vitro test is most predictive of therapeutic outcome. These new criteria would diminish false susceptibility without introducing false resistance.

Use of new beta-lactam antibiotics for surgical infections

The availability of beta-lactam antibiotics with extended spectra of activity against organisms commonly seen in surgical infections suggests that aminoglycoside-based therapy is no longer needed for most such community-acquired infections. The primary problems with specific beta-lactams are lack of activity against Bacteroides species and variable activity against Pseudomonas aeruginosa and enterococci. The pharmacokinetic properties of the newer beta-lactams vary considerably. This variation suggests specific settings in which these properties may be taken advantage of to improve clinical outcome.

Emergence of resistance during beta-lactam therapy of gram-negative infections. Bacterial mechanisms and medical responses

Some Gram-negative, non-fastidious bacilli, although classified as susceptible by conventional susceptibility testing methods, become resistant during therapy with the newer beta-lactam compounds. Emergence of resistance results primarily from the selection of resistant clones pre-existing within the susceptible bacterial populations. Most of the resistant clones produce large amounts of beta-lactamases which inhibit the beta-lactam antibiotics by hydrolysis, rather than by binding. In addition, resistant clones can limit the penetration of beta-lactam molecules through the outer membrane by a decreased expression of their porins. Less commonly, when beta-lactamase activity together with alteration of the permeability barrier does not prevent the access of the antibiotic molecules to their target, altered penicillin-binding proteins (PBPs) can produce resistance. However, the risk of resistance emerging during therapy varies with the beta-lactam drug administered. Some compounds such as cefpirome, BMY 28142, SCH 34343, or imipenem appear to be associated with a low risk. In addition, emergence of resistance can be reduced by using higher dosages of beta-lactam agents, or by combining them with other drugs such as aminoglycosides or quinolones.

Contribution of beta-lactamase hydrolysis and outer membrane permeability to ceftriaxone resistance in Enterobacter cloacae

Mechanisms of ceftriaxone resistance were examined in Enterobacter cloacae. Clones were selected from four strains: susceptible (S), resistant (R1), selected by plating on ceftriaxone-containing agar, and highly resistant (R2), selected in ceftriaxone-treated mice infected with S clones. According to 14C-labeled beta-lactam binding assays, ceftriaxone resistance was not associated with altered target proteins. R1 and R2 clones stably produced 50 to 1,500 times more beta-lactamase than S clones; this production increased after cefoxitin induction in all S and some R1 clones. Experiments conducted with strain 218 suggested that ceftriaxone resistance involved beta-lactamase hydrolysis. Half-lives for the beta-lactamase-beta-lactam complexes at 37 degrees C were 0.4 and 2.2 min for ceftriaxone and Sch 34343, a drug not affected by the resistance, respectively; in chromatography experiments, 218 intact R1 cells (2 x 10(9) to 3 x 10(9) CFU) suspended in ceftriaxone-containing buffer (2 micrograms/ml) hydrolyzed 80% of the antibiotic in 30 min. Three observations also suggested decreased permeability in some clones, (i) Most of the R1 and R2 clones showed decreased expression of outer membrane proteins of 37,000 to 38,000 molecular weight (37K to 38K proteins) by electrophoresis, often associated with increased amounts of 42K protein. (ii) [14C]Sch 34343 labeling of intact cells proceeded more slowly in 218 R2 (with altered 37K to 38K proteins) than in 218 R1 (without this alteration), a difference persisting after competition with unlabeled cloxacillin. Delays in binding were not caused by different enzymatic activities, since 218 R1 and 218 R2 produce, in similar amounts, beta-lactamases undistinguishable in isoelectric point and Km of cephaloridine. (iii) Intact cells from 218 R2 hydrolyzed ceftriaxone more slowly (20% in 30 min) than did those from 218 R1. In 218 R1, beta-lactamase overproduction was responsible for a 15- to 200-fold increase in the MIC's of ceftriaxone, ceftazidime, carbenicillin, piperacillin, moxalactam, aztreonam, carumonam, and BMY 28142. Imipenem and Sch 34343 were not affected; an additional three- to fivefold increase in the MIC's of these antibiotics (with the exception of piperacillin, imipenem, Sch 34343), seen with 218 R2, was associated with decreased permeability.

Emergence of resistance in gram-negative bacteria during therapy with expanded-spectrum cephalosporins

To assess the clinical importance of emergence of beta-lactam resistance caused by stable derepression of chromosomal beta-lactamases, sequential cultures from patients treated with expanded-spectrum cephalosporins were monitored for the persistence of bacteria possessing these enzymes. Antibiotic susceptibilities and beta-lactamase production before and after cefoxitin induction were determined in sequential isolates of individual bacterial strains. Of 49 strains isolated from 44 patients, 25 strains (51%) were eradicated by cephalosporin therapy, 17 strains (35%) persisted with unchanged susceptibility in sequential cultures, and 7 strains (14%) from 7 patients developed multiple beta-lactam resistance during cephalosporin therapy. In 6 of the 7 strains, resistance was associated with stable derepression of beta-lactamases. In the patient group whose strains developed resistance, subsequent use of non-beta-lactam antibiotics was more frequent and mortality was higher.

Clinical importance of inducible beta-lactamases in gram-negative bacteria

The clinical problems caused by inducible beta-lactamases in certain gram-negative bacteria are being recognized with increasing frequency. These problems include the rapid emergence of multiple beta-lactam resistance during therapy with many of the newer beta-lactam antibiotics. Such multiply resistant organisms are now spreading within the hospital and have become important nosocomial pathogens. This has been a particularly difficult problem for intensive care units, cystic fibrosis centers and burn units where there are clusters of patients who are highly susceptible to infections with organisms like Enterobacter spp., Serratia spp. and Pseudomonas aeruginosa, which possess inducible beta-lactamases. Only through an awareness of these problems, their cause, and restriction of the use of certain newer beta-lactam antibiotics can these problems be controlled.

Resistant strains of Pseudomonas aeruginosa isolated after exposure to several beta-lactam antibiotics

Successive transfer of three clinical isolates of Pseudomonas aeruginosa in liquid medium containing serial dilutions of several beta-lactam antibiotics was used to isolate resistant variants. The alpha-carboxy-penicillins (carbenicillin and ticarcillin), the acylureidopenicillins (piperacillin and azlocillin) and cephalosporins (moxalactam, cefoperazone, cefsulodin and ceftazidime) were used as the selective antibiotics. Resistant variants were isolated from two of the three strains (strains 27 and 45), using an inoculum size of 10(4)-10(5) CFU/ml, which showed a mean 5 to 8-fold increase in MIC for most of the selected antibiotics. The 27-carbenicillin and 27-cefsulodin resistant variants showed beta-lactamase production similar to that of the parent. However, alterations were found in outer-membrane proteins and lipopolysaccharides. With azlocillin, moxalactam and ceftazidime as the selective antibiotics, resistant variants were isolated from strains 27 and 45 which showed a stable increased constitutive beta-lactamase production. From the third strain, 9150, the only variants isolated showed a two dilution-step increase in MIC to the antibiotics tested. The beta-lactamase production, outer-membrane proteins and lipopolysaccharides of these variants were similar to those of the parent.

Enterobacter meningitis--treatment complicated by emergence of mutants resistant to cefotaxime

A case of Enterobacter cloacae meningitis in a postoperative patient is reported. A slow response to cefotaxime necessitated the use of gentamicin and trimethoprim-sulfamethoxazole for cure. Two types of resistance in the strain of E. cloacae isolated to cefotaxime were demonstrated: an inducible beta-lactamase that likely was the cause of the poor response to cefotaxime and a constitutive beta-lactamase in a mutant strain detected by a disc susceptibility test.

Differences in drug susceptibility between isolates of Pseudomonas cepacia recovered from patients with cystic fibrosis and other sources and its relationship to beta-lactamase focusing pattern

Pseudomonas cepacia, a significant pulmonary pathogen among children with cystic fibrosis (CF), often possesses an inducible beta-lactamase. The beta-lactamase isoelectric focusing pattern and beta-lactam susceptibility of CF and non-CF isolates of P. cepacia were compared. Against all of the test strains, ceftazidime and piperacillin were more effective than aztreonam. More CF isolates were resistant to 8 micrograms/ml of ceftazidime than non-CF isolates. Isoelectric focusing of cefoxitin-induced, cell-free preparations of the CF isolates produced significantly more bands than comparable preparations of non-CF isolates. Organisms producing a beta-lactamase band that focused in the pH range of 8.5 to 8.7 were significantly more resistant to 8 micrograms/ml of ceftazidime than other isolates. The increased resistance of CF isolates of P. cepacia to ceftazidime may be the result of the production of a specific bacterial beta-lactamase.

Multiply resistant mutants of Enterobacter cloacae selected by beta-lactam antibiotics

Mutants of Enterobacter cloacae, selected in vitro with ceftriaxone, ceftazidime, carumonam, or aztreonam, fell into several distinct classes. Three mutants highly resistant to nearly all beta-lactam antibiotics were stably derepressed for beta-lactamase production. Although no other changes could be detected, virulence in a mouse septicemia model was decreased in two of these mutants. One mutant, 908-Ssi, showed selectively decreased susceptibility to ampicillin and cefotetan. A change in beta-lactamase expression was thought to be responsible for this. Alterations in the production of two outer membrane proteins with molecular sizes of 36.5 and 39 kilodaltons were responsible for multiple antibiotic resistance in two mutants, both of which acquired a low level of resistance to beta-lactam antibiotics. Whereas one of the mutants, AMA-R, simultaneously acquired resistance to chloramphenicol and trimethoprim, the other, AZT-R, became hypersusceptible to these and other hydrophobic agents. Both strains had drastically reduced virulence in mice.

Beta-lactamase stability of cefpirome (HR 810), a new cephalosporin with a broad antimicrobial spectrum

Cefpirome was highly stable to hydrolysis by various beta-lactamases, although it was hydrolyzed to some extent by R plasmid-mediated penicillinase of Richmond-Sykes type Va/b and by chromosomal cephalosporinases from Bacteroides species. The compound had a very low affinity for cephalosporinases from Enterobacter cloacae, Citrobacter freundii, Serratia marcescens, and Proteus vulgaris. Cefpirome showed strong antimicrobial activity against eight beta-lactamase (cephalosporinase)-producing strains which have become resistant to broad-spectrum cephalosporins; especially against E. cloacae and C. freundii, it had the highest activity among the cephalosporins used. Its activity against ampicillin-resistant R plasmid-containing transconjugant isolates of Escherichia coli was as high as that against the recipient strain E. coli chi 1037. The inducer activity of cefpirome in S. marcescens and P. vulgaris increased dose dependently, whereas cephamycin derivatives showed high inducer activity at low concentrations. A relatively low affinity of cefpirome for beta-lactamases is considered to be one of the reasons for its high antimicrobial activity against such enzyme-producing strains. In addition, other factors such as good penetration through the outer membrane and affinity for the target sites may also be involved in the high activity of cefpirome.

Resistance to beta-lactams in Enterobacteriaceae: distribution of phenotypes related to beta-lactamase production

Phenotypes of susceptibility to amoxycillin (Amo), ticarcillin (Tic), cephalothin (Ctn) were determined in 1366 isolates of Enterobacteriaceae by disk method and beta-lactamases were identified in 243 strains belonging to different phenotypes of amoxycillin-resistant strains. AmoR TicR CtnS strains (25%) were penicillinase producers and all of them were susceptible to the combination amoxycillin/clavulanic acid (Amo/CA) and ticarcillin/clavulanic acid (Tic/CA). Amo1/R TicS CtnR strains (12%) were cephalosporinase producers and resistance to Amo/CA was observed, except for Proteus vulgaris. AmoR TicR CtnR strains (18%) often produced two beta-lactamases (penicillinase and cephalosporinase) and they were resistant to Amo/CA; in this group, susceptibility to Tic/CA depends on the nature and the amount of the beta-lactamase produced, except for Serratia marcescens for which antibiotic resistance is probably due to other mechanisms. Tic/CA resistance was mainly found in Serratia marcescens (41%) and Enterobacter cloacae (36%).