Molecular mechanism of Hfq-dependent sRNA1039 and sRNA1600 regulating antibiotic resistance and virulence in Shigella sonnei.

Bacillary dysentery caused by Shigella spp. is a significant concern for human health. Small non-coding RNA (sRNA) plays a crucial role in regulating antibiotic resistance and virulence in Shigella spp. However, the specific mechanisms behind this phenomenon are still not fully understood. This study discovered two sRNAs (sRNA1039 and sRNA1600) that may be involved in bacterial resistance and virulence. By constructing deletion mutants (WT/ΔSR1039 and WT/ΔSR1600), this study found that the WT/ΔSR1039 mutants caused a two-fold increase in sensitivity to ampicillin, gentamicin and cefuroxime, and the WT/ΔSR1600 mutants caused a two-fold increase in sensitivity to cefuroxime. Furthermore, the WT/ΔSR1600 mutants caused a decrease in the adhesion and invasion of bacteria to HeLa cells (P<0.01), and changed the oxidative stress level of bacteria to reduce their survival rate (P<0.001). Subsequently, this study explored the molecular mechanisms by which sRNA1039 and sRNA1600 regulate antibiotic resistance and virulence. The deletion of sRNA1039 accelerated the degradation of target gene cfa mRNA and reduced its expression, thereby regulating the expression of pore protein gene ompD indirectly and negatively to increase bacterial sensitivity to ampicillin, gentamicin and cefuroxime. The inactivation of sRNA1600 reduced the formation of persister cells to reduce resistance to cefuroxime, and reduced the expression of type-III-secretion-system-related genes to reduce bacterial virulence by reducing the expression of target gene tomB. These results provide new insights into Hfq-sRNA-mRNA regulation of the resistance and virulence network of Shigella sonnei, which could potentially promote the development of more effective treatment strategies.

Mechanism analysis for the process-dependent driven mode of NaHCO3 in algal antibiotic removal: efficiency, degradation pathway and metabolic response.

This work provided a comprehensive perspective to investigate the performance of NaHCO3-driving effect and mechanism including the antibiotic removal, degradation pathway and metabolites analysis, and the algal physiological response during the removal process. Cefuroxime sodium was selected as the target antibiotic. Our results showed that NaHCO3 did not facilitate self-decomposition of the target antibiotic, while drove the improvement on the removal capacity of every algal cell, which then attributed to the total removal efficiency. After 24 h, there was an improvement on the removal rate of the target antibiotic (from 10.21% to 92.89%) when NaHCO3 was added. The degradation pathway of the target antibiotic was confirmed by the formation of three main products (M1, M2 and M3), and the degradation process, that from M1 to M2 and M2 to M3, was accelerated by the existence of NaHCO3. Besides, a 4-stage model illustrated the relationship between NaHCO3 and antibiotic removal process. Moreover, algal culture that supplemented with NaHCO3 demonstrated a better growth capacity. A large increase in the content of chlorophyll a and a moderate increase in the activity of two carbon metabolic enzymes (RuBisCO and CA) might be viewed as a positive response of the algae during the NaHCO3-driving process.

The biodegradation of cefuroxime, cefotaxime and cefpirome by the synthetic consortium with probiotic Bacillus clausii and investigation of their potential biodegradation pathways.

Cephalosporin residues in the environment are a great concern, but bioremediation options do exist. Bacillus clausii T reached a removal rate of 100% within 8 h when challenged with a mixture of cefuroxime (CFX), cefotaxime (CTX), and cefpirome (CPR). The co-culture of B. clausii T and B. clausii O/C displayed a higher removal efficiency for the mixture of CFX, CTX and CPR than a pure culture of B. clausii O/C. B. clausii T alleviated the biotoxicity of CFX and CPR. What's more, the biotoxicity of for CFX and CPR transformation products released by the co-culture of B. clausii T and B. clausii O/C was lower than that in pure cultures. Real-time PCR was applied to detect the changes in the expression levels of the relevant antibiotic-resistance genes of B. clausii T during CFX and CPR degradation. The results indicated that CFX and CPR enhanced the expression of the ß-lactamase gene bcl1. Hydrolysis, deacetylation and decarboxylation are likely the major mechanisms of CTX biodegradation by B. clausii. These results demonstrate that B. clausii T is a promising strain for the bioremediation of environmental contamination by CFX, CTX, and CPR.

Crystal Structures of Penicillin-Binding Protein D2 from Listeria monocytogenes and Structural Basis for Antibiotic Specificity.

ß-Lactam antibiotics that inhibit penicillin-binding proteins (PBPs) have been widely used in the treatment of bacterial infections. However, the molecular basis underlying the different inhibitory potencies of ß-lactams against specific PBPs is not fully understood. Here, we present the crystal structures of penicillin-binding protein D2 (PBPD2) from Listeria monocytogenes, a Gram-positive foodborne bacterial pathogen that causes listeriosis in humans. The acylated structures in complex with four antibiotics (penicillin G, ampicillin, cefotaxime, and cefuroxime) revealed that the ß-lactam core structures were recognized by a common set of residues; however, the R1 side chains of each antibiotic participate in different interactions with PBPD2. In addition, the structural complementarities between the side chains of ß-lactams and the enzyme were found to be highly correlated with the relative reactivities of penam or cephem antibiotics against PBPD2. Our study provides the structural basis for the inhibition of PBPD2 by clinically important ß-lactam antibiotics that are commonly used in listeriosis treatment. Our findings imply that the modification of ß-lactam side chains based on structural complementarity could be useful for the development of potent inhibitors against ß-lactam-resistant PBPs.

QbD-Oriented Development and Characterization of Effervescent Floating-Bioadhesive Tablets of Cefuroxime Axetil.

The objective of the present studies was systematic development of floating-bioadhesive gastroretentive tablets of cefuroxime axetil employing rational blend of hydrophilic polymers for attaining controlled release drug delivery. As per the QbD-based approach, the patient-centric target product profile and quality attributes of tablet were earmarked, and preliminary studies were conducted for screening the suitability of type of polymers, polymer ratio, granulation technique, and granulation time for formulation of tablets. A face-centered cubic design (FCCD) was employed for optimization of the critical material attributes, i.e., concentration of release controlling polymers, PEO 303 and HPMC K100 LV CR, and evaluating in vitro buoyancy, drug release, and ex vivo mucoadhesion strength. The optimized formulation was embarked upon through numerical optimization, which yield excellent floatation characteristic with drug release control (i.e., T 60% > 6 h) and bioadhesion strength. Drug-excipient compatibility studies through FTIR and P-XRD revealed the absence of any interaction between the drug and polymers. In vivo evaluation of the gastroretentive characteristics through X-ray imaging and in vivo pharmacokinetic studies in rabbits revealed significant extension in the rate of drug absorption (i.e., T max, K a, and MRT) from the optimized tablet formulation as compared to the marketed formulation. Successful establishment of various levels of in vitro/in vivo correlations (IVIVC) substantiated high degree of prognostic ability of in vitro dissolution conditions in predicting the in vivo performance. In a nutshell, the studies demonstrate successful development of the once-a-day gastroretentive formulations of cefuroxime axetil with controlled drug release profile and improved compliance.

Molecular dynamics simulation of the complex PBP-2x with drug cefuroxime to explore the drug resistance mechanism of Streptococcus suis R61.

Drug resistance of Streptococcus suis strains is a worldwide problem for both humans and pigs. Previous studies have noted that penicillin-binding protein (PBPs) mutation is one important cause of ß-lactam antibiotic resistance. In this study, we used the molecular dynamics (MD) method to study the interaction differences between cefuroxime (CES) and PBP2x within two newly sequenced Streptococcus suis: drug-sensitive strain A7, and drug-resistant strain R61. The MM-PBSA results proved that the drug bound much more tightly to PBP2x in A7 (PBP2x-A7) than to PBP2x in R61 (PBP2x-R61). This is consistent with the evidently different resistances of the two strains to cefuroxime. Hydrogen bond analysis indicated that PBP2x-A7 preferred to bind to cefuroxime rather than to PBP2x-R61. Three stable hydrogen bonds were formed by the drug and PBP2x-A7, while only one unstable bond existed between the drug and PBP2x-R61. Further, we found that the Gln569, Tyr594, and Gly596 residues were the key mutant residues contributing directly to the different binding by pair wise energy decomposition comparison. By investigating the binding mode of the drug, we found that mutant residues Ala320, Gln553, and Thr595 indirectly affected the final phenomenon by topological conformation alteration. Above all, our results revealed some details about the specific interaction between the two PBP2x proteins and the drug cefuroxime. To some degree, this explained the drug resistance mechanism of Streptococcus suis and as a result could be helpful for further drug design or improvement.

Mutations in Streptococcus pneumoniae penicillin-binding protein 2x: importance of the C-terminal penicillin-binding protein and serine/threonine kinase-associated domains for beta-lactam binding.

Penicillin-binding protein 2x (PBP2x) mutations that occur during the selection with beta-lactams are located within the central penicillin-binding/transpeptidase (TP) domain, and are believed to mediate resistance by interfering with the formation of a covalent complex of the active site serine with the antibiotic. We now investigated the effect of two point mutations found in two independently obtained laboratory mutants that are located at the surface of the TP domain with their side chains facing outside (G422D respectively R426C). They have no significant effect on resistance to cefotaxime in vivo or on binding to Bocillin™FL to the active site in vitro using purified PBP2x derivatives, thus apparently do not affect the active site directly. In contrast, in silico modeling revealed that they affect van der Waal's interactions with the PASTA1 (PBP and serine/threonine kinase associated) domain of the C-terminal extension and a noncovalent cefuroxime molecule found in the X-ray structure of an acylated PBP2x, suggesting some effect of the mutations on the interaction of the TP domain with PASTA1 and/or with the antibiotic associated with PASTA1. The effect of the PASTA domains on covalent binding of PBP2x to Bocillin FL was then investigated using a series of soluble truncated PBP2x derivatives. Deletion of 127 C-terminal residues, that is, of both PASTA domains, decreased binding dramatically by ∼90%. Surprisingly, deletion of only 40 amino acids resulted in the same phenotype, whereas the absence of 30 amino acids affected binding marginally by 10%, documenting a crucial role of the C-terminal domain for beta-lactam binding.

Biotic and abiotic degradation of four cephalosporin antibiotics in a lake surface water and sediment.

Cephalosporins are widely used veterinary and human antibiotics, but their environmental fate and impacts are still unclear. We studied degradation of four cephalosporins (cefradine, cefuroxime, ceftriaxone, and cefepime) from each generation in the surface water and sediment of Lake Xuanwu, China. The four cephalosporins degraded abiotically in the surface water in the dark with half-lives of 2.7-18.7d, which were almost the same as that in sterilized surface water. Under exposure to simulated sunlight, the half-lives of the cephalosporins decreased significantly to 2.2-5.0d, with the maximal decrease for ceftriaxone from 18.7d in the dark to 4.1d under the light exposure. Effects of dissolved organic matter (DOM) and nitrate on photodegradation of the cephalosporins were compound-specific. While DOM (5 mg L(-1)) stimulated the photodegradation of only cefradine (by 9%) and cefepime (by 34%), nitrate (10 microM) had effects only on cefepime (stimulation by 13%). Elimination rates of the cephalosporins in oxic sediment (half-lives of 0.8-3.1d) were higher than in anoxic sediment (half-lives of 1.1-4.1d), mainly attributed to biodegradation. The data indicate that abiotic hydrolysis (for cefradine, cefuroxime, and cefepime) and direct photolysis (for ceftriaxone) were the primary processes for elimination of the cephalosporins in the surface water of the lake, whereas biodegradation was responsible for the elimination of the cephalosporins in the sediment. Further studies are needed on chemical structure, toxicity, and persistence of transformation products of the cephalosporins in the environment.

Characterization of a new metallo-beta-lactamase gene, bla(NDM-1), and a novel erythromycin esterase gene carried on a unique genetic structure in Klebsiella pneumoniae sequence type 14 from India.

A Swedish patient of Indian origin traveled to New Delhi, India, and acquired a urinary tract infection caused by a carbapenem-resistant Klebsiella pneumoniae strain that typed to the sequence type 14 complex. The isolate, Klebsiella pneumoniae 05-506, was shown to possess a metallo-beta-lactamase (MBL) but was negative for previously known MBL genes. Gene libraries and amplification of class 1 integrons revealed three resistance-conferring regions; the first contained bla(CMY-4) flanked by ISEcP1 and blc. The second region of 4.8 kb contained a complex class 1 integron with the gene cassettes arr-2, a new erythromycin esterase gene; ereC; aadA1; and cmlA7. An intact ISCR1 element was shown to be downstream from the qac/sul genes. The third region consisted of a new MBL gene, designated bla(NDM-1), flanked on one side by K. pneumoniae DNA and a truncated IS26 element on its other side. The last two regions lie adjacent to one another, and all three regions are found on a 180-kb region that is easily transferable to recipient strains and that confers resistance to all antibiotics except fluoroquinolones and colistin. NDM-1 shares very little identity with other MBLs, with the most similar MBLs being VIM-1/VIM-2, with which it has only 32.4% identity. As well as possessing unique residues near the active site, NDM-1 also has an additional insert between positions 162 and 166 not present in other MBLs. NDM-1 has a molecular mass of 28 kDa, is monomeric, and can hydrolyze all beta-lactams except aztreonam. Compared to VIM-2, NDM-1 displays tighter binding to most cephalosporins, in particular, cefuroxime, cefotaxime, and cephalothin (cefalotin), and also to the penicillins. NDM-1 does not bind to the carbapenems as tightly as IMP-1 or VIM-2 and turns over the carbapenems at a rate similar to that of VIM-2. In addition to K. pneumoniae 05-506, bla(NDM-1) was found on a 140-kb plasmid in an Escherichia coli strain isolated from the patient's feces, inferring the possibility of in vivo conjugation. The broad resistance carried on these plasmids is a further worrying development for India, which already has high levels of antibiotic resistance.

Target affinities of faropenem to and its impact on the morphology of gram-positive and gram-negative bacteria.

Faropenem is a new oral beta-lactam antibiotic unique from carbapenems and other available beta-lactams. Determinants of the in vitro activity of beta-lactam antibiotics include affinity to penicillin-binding proteins (PBPs) and beta-lactamase stability. In this study, the binding affinity of faropenem to various PBPs and its impact on the morphology of Staphylococcus aureus and Escherichia coli were evaluated. In general, faropenem demonstrated high binding affinity to high-molecular-weight PBPs but low affinity to low-molecular-weight PBPs. In S. aureus and Streptococcus pneumoniae, faropenem exhibited high binding affinity to PBP1, followed by PBP3 and PBP2. In E. coli, faropenem showed the highest affinity for PBP2, followed by PBP1A, PBP1B, PBP3 and PBP4. In Proteus vulgaris, binding was highest to PBP4, followed by PBP1A, PBP2 and PBP3. In Serratia marcescens, faropenem bound preferentially to PBP2 and PBP4. Exposure of S. aureus to faropenem at minimum inhibitory concentrations (MICs) of 1/8 or 1/4 resulted in irregular septum formation. At 1x MIC or higher, a larger number of lysed cells were observed. Exposure of E. coli to 1/8x MIC or 1/4x MIC also induced changes in cellular shape; the normal rod-shaped form changed to a spherical form in a time-dependent manner. After exposure of E. coli to 1x MIC for 2 h, bulging-shaped E. coli cells were observed and after 4 h of exposure cell lysis was demonstrated. In the presence of 4x MIC, spheroplast-like forms and cell lysis were observed. The morphological changes triggered by faropenem are in agreement with the PBP binding affinities reported. Thus, the high binding affinities of faropenem to PBPs from gram-negative and gram-positive bacteria are mirrored by its pronounced and concentration-dependent bactericidal effect.

Pharmacokinetics of antibiotic prophylaxis in major orthopedic surgery and blood-saving techniques.

The pharmacokinetics of cefuroxime, cefotiam, cefamandole, and ampicillin/sulbactam were randomly measured in 40 patients undergoing major orthopedic surgery associated with high blood and volume turnover and intraoperative blood salvage. Serum and bone concentrations and the pharmacokinetics occurring in the context of these procedures were measured. No changes in elimination half-life relative to a normal population occurred with cefuroxime, cefotiam, and ampicillin. Serum and tissue concentrations were slightly lower with cefamandole and sulbactam, but reapplication of the initial dose was required with all antibiotics 4 hours after the first application.

The crystal structure of the penicillin-binding protein 2x from Streptococcus pneumoniae and its acyl-enzyme form: implication in drug resistance.

Penicillin-binding proteins (PBPs), the primary targets for beta-lactam antibiotics, are periplasmic membrane-attached proteins responsible for the construction and maintenance of the bacterial cell wall. Bacteria have developed several mechanisms of resistance, one of which is the mutation of the target enzymes to reduce their affinity for beta-lactam antibiotics. Here, we describe the structure of PBP2x from Streptococcus pneumoniae determined to 2.4 A. In addition, we also describe the PBP2x structure in complex with cefuroxime, a therapeutically relevant antibiotic, at 2.8 A. Surprisingly, two antibiotic molecules are observed: one as a covalent complex with the active-site serine residue, and a second one between the C-terminal and the transpeptidase domains. The structure of PBP2x reveals an active site similar to those of the class A beta-lactamases, albeit with an absence of unambiguous deacylation machinery. The structure highlights a few amino acid residues, namely Thr338, Thr550 and Gln552, which are directly related to the resistance phenomenon.

Mutations in the active site of penicillin-binding protein PBP2x from Streptococcus pneumoniae. Role in the specificity for beta-lactam antibiotics.

Penicillin-binding protein 2x (PBP2x) isolated from clinical beta-lactam-resistant strains of Streptococcus pneumoniae (R-PBP2x) have a reduced affinity for beta-lactam antibiotics. Their transpeptidase domain carries numerous substitutions compared with homologous sequences from beta-lactam-sensitive streptococci (S-PBP2x). Comparison of R-PBP2x sequences suggested that the mutation Gln552 --> Glu is important for resistance development. Mutants selected in the laboratory with cephalosporins frequently contain a mutation Thr550 --> Ala. The high resolution structure of a complex between S-PBP2x* and cefuroxime revealed that Gln552 and Thr550, which belong to strand beta3, are in direct contact with the cephalosporin. We have studied the effect of alterations at positions 552 and 550 in soluble S-PBP2x (S-PBP2x*) expressed in Escherichia coli. Mutation Q552E lowered the acylation efficiency for both penicillin G and cefotaxime when compared with S-PBP2x*. We propose that the introduction of a negative charge in strand beta3 conflicts with the negative charge of the beta-lactam. Mutation T550A lowered the acylation efficiency of the protein for cefotaxime but not for penicillin G. The in vitro data presented here are in agreement with the distinct resistance profiles mediated by these mutations in vivo and underline their role as powerful resistance determinants.

In vitro anti-staphylococcal activity of heparinized biomaterials bonded with combinations of rifampicin.

Biomaterial implants in various human body tissues are highly susceptible to bacterial colonization. We report here on the coating of heparinized biomaterials with heparin binding extracellular matrix proteins giving special regard to the efficient adsorption and slow release of antibiotics. Heparin was partially degraded and the resulting fragments were covalently end-point attached to 0.5 cm long silicone biomaterial surface. Collagen type I was immobilized on the heparinized biomaterials and then cross-linked with acyl-azide or carbodiimide. Finally, the resulting biosurfaces were exposed to antibiotics, i.e. rifampicin in combination with cefuroxime, fusidic acid, ofloxacin or vancomycin, respectively. The antibiotic bonded biomaterials were evaluated for their anti-staphylococcal activity after elution in NaCl, serum or blood by measuring the zones of inhibition for S. epidermidis strain RP12. Furthermore, we examined the in-vitro colonization resistance to S. epidermidis RP12 for these combinations of rifampicin-bonded biomaterials by an ATP bioluminescence assay. The ATP measurements showed that initially adherent bacteria were eradicated from the polymer surface, for at least 24 or 48 h (fusidic acid > cefuroxime > vancomycin > ofloxacin). The anti-staphylococcal activity of rifampicin-fusidic acid bonded heparinized biomaterials seems of sufficient duration and efficacy to merit testing in an animal model.

Concentration of cefuroxime in middle ear effusion of children with acute otitis media.

BACKGROUND: Antibiotic concentrations in serum and middle ear effusion are important in determining therapeutic success in acute otitis media. For beta-lactams the most relevant pharmacokinetic index for clinical efficacy is the time for which serum concentrations exceed the minimum inhibitory concentration (MIC) of the pathogen, which should be at least 40 to 50% of the dosing interval. METHODS: In this open, single center study, the concentration of cefuroxime achieved in the serum and middle ear effusion of pediatric acute otitis media patients with purulent effusion was assessed between 2 and 5 h after a single oral dose of 15 mg/kg cefuroxime axetil suspension. RESULTS: Serum concentrations of cefuroxime ranged from 2.8 to 7.3 microg/ml and were consistent with the results of previous pharmacokinetic study. These results show that serum concentrations of cefuroxime remain above the MIC90 (2.0 microg/ml) for Streptococcus pneumoniae, Haemophilus influenzae and Moraxella catarrhalis for at least 5 h (42%) of the 12-h dosing interval. Cefuroxime was detected in 14 of 17 (82%) middle ear effusion samples and ranged from 0.2 to 3.6 microg/ml, indicating that cefuroxime penetrates well into the middle ear. CONCLUSIONS: Cefuroxime is well-absorbed and penetrates well into the middle ear after oral administration of cefuroxime axetil suspension.

Site-directed mutagenesis of glutamate 166 in two beta-lactamases. Kinetic and molecular modeling studies.

The catalytic pathway of class A beta-lactamases involves an acyl-enzyme intermediate where the substrate is ester-linked to the Ser-70 residue. Glu-166 and Lys-73 have been proposed as candidates for the role of general base in the activation of the serine OH group. The replacement of Glu-166 by an asparagine in the TEM-1 and by a histidine in the Streptomyces albus G beta-lactamases yielded enzymes forming stable acyl-enzymes with beta-lactam antibiotics. Although acylation of the modified proteins by benzylpenicillin remained relatively fast, it was significantly impaired when compared to that observed with the wild-type enzyme. Moreover, the E166N substitution resulted in a spectacular modification of the substrate profile much larger than that described for other mutations of Omega-loop residues. Molecular modeling studies indicate that the displacement of the catalytic water molecule can be related to this observation. These results confirm the crucial roles of Glu-166 and of the "catalytic" water molecule in both the acylation and the deacylation processes.

Cure for a crisis?

The first look at the three-dimensional structure of an essential penicillin binding protein from a human pathogen, and its complex with a beta-lactam antibiotic provides hope for the future design of improved antibiotics.

Esters of cephalosporins. Part IV. Hydrolysis of 1-acetoxyethyl ester of cefuroxime in vitro and in vivo.

Hydrolysis of 1-acetoxyethyl ester of cefuroxime [I] in blood was studied in vitro and in vivo. In vitro [I] hydrolyzes to biological active cefuroxime [II] and at the same time it undergoes isomerization to isomer delta 2 of 1-acetoxyethyl ester of cefuroxime [IV] and next hydrolyzes to biological inactive isomer delta 2 of cefuroxime [V]. As a result of hydrolysis [I] in vivo only [II] is formed.

TEM beta-lactamase mutants hydrolysing third-generation cephalosporins. A kinetic and molecular modelling analysis.

The catalytic properties of six "natural" mutants of the TEM-1 beta-lactamase have been studied in detail, with special emphasis on their activity versus third-generation cephalosporins. On the basis of the recently determined high-resolution structure of the wild-type enzyme, and of the substrates' structures optimized by the AMI quantum chemistry method, we have attempted to explain the influences of the mutations on the substrate profiles of the enzymes. Some of the kinetic results have thus received a satisfactory, semi-quantitative interpretation, especially in the case of single mutations. Analysis of the double mutants proved more hazardous. Extending the comparison to some other class A beta-lactamases showed that similar properties could result from different sequences, supplying an interesting example of convergent evolution within a generally diverging family.

The renal clearance of cefuroxime and ceftazidime and the effect of probenecid on their tubular excretion.

1. The renal tubular excretion of cefuroxime and ceftazidime in relation to the coadministration of probenecid was investigated in eight and two healthy subjects, respectively. 2. Cefuroxime or ceftazidime were administered by i.v. infusion and 1 g probenecid was administered orally after steady state plasma concentrations of the cephalosporin were reached. 3. In a second session the same antibiotic was administered at increasing infusion rates such that three different levels of plasma drug concentration were achieved. 4. The renal clearance of antibiotic was calculated based upon unbound plasma concentration, and tubular clearance was estimated by subtracting inulin clearance from the renal clearance of the antibiotic. 5. Non-linear regression analysis was used to estimate parameters describing the saturability of tubular excretion and the effect of probenecid inhibition, i.e. EC50 and Rtub,max, could be established for cefuroxime: EC50 was 248 (s.d. 130) mg l-1 and Rtub,max was 1.852 (s.d. 0.577) mg h-1. Tubular excretion of ceftazidime was practically zero. The EC50 of probenecid for inhibition of the tubular excretion of cefuroxime was 0.80 (s.d. 0.31) mg l-1. 6. The results indicate that in the therapeutic plasma concentration range of cefuroxime its renal clearance is not saturated. Probenecid at therapeutic doses will block tubular excretion of cefuroxime almost completely.